Multicast collaborative erasure encoding and distributed parity protection

ABSTRACT

The present disclosure provides methods and systems for multicast collaborative erasure encoding and methods and systems for distributed parity protection. One embodiment relates to a method of multicast collaborative erasure encoding of a chunk stored in a distributed object storage cluster. A roll-call request is multicast to every storage server in a negotiating group for the chunk. Roll-call inventory responses are generated and multicast by every storage server in the negotiating group. The roll-call inventory responses are collected by every storage server in the negotiating group from other storage servers in the negotiating group to form a set of roll-call inventory responses. A logical evaluation of the set of roll-call inventory responses may then be performed by every storage server in the negotiating group. Other embodiments, aspects and features are also disclosed.

CROSS-REFERENCE TO RELATED APPLICATION(S)

The present application is a divisional application of U.S. patent application Ser. No. 14/832,075, filed Aug. 21, 2015, the disclosure of which is hereby incorporated by reference in its entirety. U.S. patent application Ser. No. 14/832,075 claims the benefit of U.S. Provisional Patent Application No. 62/040,962, filed Aug. 22, 2014, the disclosure of which is hereby incorporated by reference in its entirety. U.S. patent application Ser. No. 14/832,075 also claims the benefit of U.S. Provisional Patent Application No. 62/098,727, filed Dec. 31, 2014, the disclosure of which is hereby incorporated by reference in its entirety.

BACKGROUND Technical Field

The present disclosure relates generally to data storage systems and data communication systems.

Description of the Background Art

With the increasing amount of data being created, there is increasing demand for data storage solutions. Storing data using a cloud storage service is a solution that is growing in popularity. A cloud storage service may be publicly-available or private to a particular enterprise or organization. Popular public cloud storage services include Amazon S3™, the Google File System, and the OpenStack Object Storage (Swift) System™.

Cloud storage systems may provide “get” and “put” access to objects, where an object includes a payload of data being stored. The payload of an object may be stored in parts referred to as “chunks”. Using chunks enables the parallel transfer of the payload and allows the payload of a single large object to be spread over multiple storage servers.

SUMMARY

The present disclosure provides methods and systems for multicast collaborative erasure encoding and methods and systems for distributed parity protection.

One embodiment relates to a method of multicast collaborative erasure encoding of a chunk stored in a distributed object storage cluster. A roll-call request is multicast to every storage server in a negotiating group for the chunk. Roll-call inventory responses are generated and multicast by every storage server in the negotiating group. The roll-call inventory responses are collected by every storage server in the negotiating group from other storage servers in the negotiating group to form a set of roll-call inventory responses. A logical evaluation of the set of roll-call inventory responses may then be performed by every storage server in the negotiating group.

Another embodiment relates to a distributed object storage system that stores objects in chunks. The system includes a plurality of storage servers communicatively interconnected by a network, and negotiating groups for the chunks. A negotiating group for a chunk comprises a group of the storage servers that are assigned to store and provide access to the chunk. A storage server in the negotiating group for the chunk includes executable code that performs steps including: multicasting a roll-call request to other storage servers in the negotiating group for the chunk; collecting roll-call inventory responses received from the other storage servers in the negotiating group for the chunk to form a set of roll-call inventory responses; and performing a logical evaluation of the set of roll-call inventory responses.

Another embodiment relates to a storage server in a distributed object storage system that stores objects in chunks. The storage server includes: a processor for executing executable code; memory for storing and accessing executable code and data; and a network connection to communicatively interconnect the storage server with other storage servers in the distributed object storage system. The executable code performs steps that include: multicasting a roll-call request to a group of storage servers that are responsible for storing and providing access to a chunk; collecting roll-call inventory responses received from the storage servers in the group to form a set of roll-call inventory responses; and performing a logical evaluation of the set of roll-call inventory responses. The logical evaluation may result in a subset of actions to be performed by the storage server.

In another embodiment, the storage server includes executable code, where the executable code performs steps that include: receiving a roll-call request for the chunk; multicasting a roll-call inventory response to the negotiating group in response to the roll-call request; collecting roll-call inventory responses received from other storage servers in the negotiating group to form a set of roll-call inventory responses; and performing a logical evaluation of the set of roll-call inventory responses. The logical evaluation may result in a subset of actions to be performed by the storage server.

Another embodiment relates to a method of distributed parity protection of a chunk stored in an object storage cluster. The chunk is stored in a plurality of erasure-encoded slices at different storage servers in the object storage cluster, wherein the plurality of erasure-encoded slices include a plurality of data stripes and at least one parity stripe. A determination is made that a data stripe of the plurality of data stripes is lost, and a further determination is made as to the surviving erasure-encoded slices of the plurality of erasure-encoded slices. The surviving erasure-encoded slices are grouped into a first set of pairs by having a first storage server holding a first slice of each pair send the first slice to a second storage server holding a second slice of the pair. The second storage server applies an operation on the first and second slices to generate a resultant slice. The resultant slices may be further grouped and operated upon until a single slice is generated, the single slice being the data stripe that was lost.

Another embodiment relates to an object storage system with distributed parity protection. The system includes a network and a plurality of storage servers communicatively interconnected by the network. The plurality of storage servers include executable code that performs the following steps: storing a chunk in a plurality of erasure-encoded slices at different storage servers, wherein the plurality of erasure-encoded slices include a plurality of data stripes and at least one parity stripe; determining that a data stripe of the plurality of data stripes is lost; determining surviving erasure-encoded slices of the plurality of erasure-encoded slices; grouping the surviving erasure-encoded slices into a first set of pairs by sending a first erasure-encoded slice of each pair from a first storage server to a second storage server that holds a second erasure-encoded slice of each pair; and operating on first and second slices of each pair in the first set of pairs to generate a set of resultant slices at the second storage server. The resultant slices may be further grouped and operated upon until a single slice is generated, the single slice being the data stripe that was lost.

Other embodiments, aspects, and features are also disclosed.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 depicts a non-blocking switch.

FIG. 2 depicts where the replicast transport layer may fit into the conventional OSI/ISO Seven Layer Model in accordance with an embodiment of the invention.

FIG. 3 is a simplified depiction of chunk transmission in an exemplary distributed storage system in accordance with an embodiment of the invention.

FIG. 4 depicts congestion on inbound links of a distributed storage system with serial transmission of chunk copies.

FIG. 5 depicts a distributed chunk put operation using relayed unicast transmission in a distributed storage system.

FIGS. 6-8 depict steps of a client-consensus-based procedure for proposing a chunk put to a distributed storage system in accordance with an embodiment of the invention.

FIGS. 9-11 depict steps of a cluster-consensus-based procedure for proposing a chunk put to a distributed storage system in accordance with an embodiment of the invention.

FIGS. 12 and 13 depict steps of a client-consensus-based procedure for proposing a chunk put to a distributed storage system with de-duplication in accordance with an embodiment of the invention.

FIGS. 14 and 15 depict steps of a cluster-consensus-based procedure for proposing a chunk put to a distributed storage system with de-duplication in accordance with an embodiment of the invention.

FIGS. 16 and 17 depict steps of a client-consensus-based procedure for requesting a chunk get from a distributed storage system in accordance with an embodiment of the invention.

FIGS. 18 and 19 depict steps of a cluster-consensus-based procedure for requesting a chunk get from a distributed storage system in accordance with an embodiment of the invention.

FIGS. 20 and 21 depict steps of a cluster-consensus-based procedure for requesting a chunk get from a distributed storage system where an additional target is requested in accordance with an embodiment of the invention.

FIGS. 22 and 23 depict a possible encoding of a generic “Replicast” message over L2 frames.

FIG. 24 depicts exemplary encoding structures for chunk put proposal messages in accordance with an embodiment of the invention.

FIG. 25 depicts exemplary encoding structures for chunk accept messages in accordance with an embodiment of the invention.

FIG. 26 depicts exemplary encoding structures for rendezvous transfer messages in accordance with an embodiment of the invention.

FIG. 27 depicts exemplary encoding structures for payload acknowledgement messages in accordance with an embodiment of the invention.

FIG. 28 depicts exemplary encoding structures for get request messages in accordance with an embodiment of the invention.

FIG. 29 depicts exemplary encoding structures for get response messages in accordance with an embodiment of the invention.

FIG. 30 depicts exemplary encoding structures for an error get response message in accordance with an embodiment of the invention.

FIG. 31 depicts a simplified example of a computer apparatus which may be configured as a client or a server in the system in accordance with an embodiment of the invention.

FIG. 32 depicts a process for weighting servers in an object storage system in accordance with an embodiment of the invention.

FIG. 33 depicts a sample assignment of server IDs to rows of a hash table for an object storage system in accordance with an embodiment of the invention.

FIG. 34 depicts processing of a chunk hash ID to determine a set of server IDs in an object storage system in accordance with an embodiment of the invention.

FIG. 35 is a flow chart of a method of multicast collaborative erasure encoding of a chunk that is stored in an object storage system in accordance with an embodiment of the invention.

FIG. 36 is a state diagram showing macro-states for chunk encoding in accordance with an embodiment of the invention.

FIG. 37 depicts a method of conventional recovery of a lost stripe from a parity stripe.

FIG. 38 depicts a method of distributed recovery of a lost stripe from a parity stripe in accordance with an embodiment of the invention.

DETAILED DESCRIPTION

I. Scalable Transport for Multicast Replication

As described herein, multicast communications may provide great value in storage networking. There are several instances where the desired distribution of information is from one sender to multiple receivers. These include:

-   1) Replication of storage content. Creating more than one replica is     generally desired to protect against the loss of individual storage     servers. -   2) Finding the most suitable set of storage servers to accept new     content. Storage servers have dynamically varying capacities and     work queue depths. Finding the servers that could store the content     most quickly allows transactions to complete in the shortest     possible time. If point-to-point protocols performed this survey,     the polling process could easily take more time than the potential     savings in time. -   3) Finding the best storage server to process a specific get request     has similar issues as finding the most suitable set of storage     servers to accept new content. -   4) Network replication to additional servers in order to create     extra replicas for caching content, distributing content to archival     storage and to remote networks comes with only minimal network     traffic increase and no increase in server operations for reading     the extra copies for these separate purposes. -   5) Enabling parallel updating of distributed content (e.g. a     Distributed Hash Allocation Table) on all cluster members.

While the value of these potential multicast communications is clear, the conventional wisdom has been that multicast cannot be reliable enough for storage, and therefore the overhead of point-to-point protocols must be tolerated in order to provide reliability. Use of multicast in storage clusters has been conventionally limited to the “keep-alive” protocols, which track the set of storage servers currently connected. Conventionally multicast messaging is not used for the storage content itself.

The present disclosure provides an effectively reliable transport layer for multicast communications. The methods disclosed herein are optimized for storage networking within a local area network with short and reasonably uniform round-trip times, but they may be layered on top of any transport services that provides an unreliable datagram service and multicast addressing.

Congestion Control in Point-to-Point Network Replication

Replicating storage over a shared network typically involves large transfers initiated independently by multiple sources. In such cases, some form of congestion control is required to avoid over-subscribing the buffering capacity of the storage network. Designing a core network to be non-blocking is feasible and desirable; however, it is currently implausible to design the target nodes with enough capacity to receive concurrent transfers from every source that might want to transmit. Moreover, even with a non-blocking core, some form of congestion control is required to allocate the bandwidth on the last link to the target servers.

In a simple solution, each content source replicates content to each distinct storage server using Unicast point-to-point reliable connections (most frequently TCP/IP). However, this solution can make the link from the content source a bottleneck that limits the speed of sending the new content into the network. According to this solution, if K is the desired replication count (e.g.) three), then the source server sends the content K times (each time over a point-to-point connection). The OpenStack Object Service (“Swift”) has this design characteristic.

Another Object Storage system, the Hadoop Distributed File System (HDFS), partially addresses this problem by serializing replication of new content. The content source puts to a first storage server, which then replicates that chunk to a second storage server, which then replicates it to a third storage server. If the server performs replication on a cut-through basis, the impact on an isolated put transaction would appear to be minimal (two times the cut-through latency, which might be as small as a single Ethernet frame for each hop).

However, such an analysis ignores the problem that the servers that are receiving chunks or objects must also retrieve and deliver content on demand. Most object storage systems operate in a write-once read-many (WORM) fashion. When a storage server takes responsibility for replicating new content the server has the limitation that the replication bandwidth is in contention with retrieval bandwidth. The only way to avoid congestion drops is to delay either the replication traffic or the retrieval traffic. The latency for puts and/or reads (gets) will suffer because of this contention.

To optimize replication of content in distributed storage systems, the presently-disclosed solution multicasts the content so as to optimize both the load on the servers and the shaping of the network traffic. While it is desirable to multicast replication traffic, doing so should not be allowed to cause network congestion and resulting dropped packets. Hence, as further disclosed herein, packet drops may be dealt with by retransmission using unicast replication on a point-to-point basis.

Reasons why Multicast was not Used in the Past

This section describes some reasons why applicants believe that multicast has not been used in the past for replication of stored content.

It would be optimum for storage networking to put the content to the network once and have that content reliably arrive at each of N destinations. One challenge to achieving this optimum result is that each chunk is typically encoded as multiple L2 (layer 2) frames. L2 networking protocols, such as Ethernet or InfiniBand™, have individual frames that are small compared to the size of the typical chunk saved in a storage system. For example in a single user Ubuntu workstation with over 584,843 files, the average file size is 240,736 bytes, (totaling ˜140 GB) although the median file size is only 3,472 bytes and the largest file is 2.9 GB. Hence, a typical put (or get) will need to deliver very many L2 frames without any portion of the message being dropped.

Modern wired networks have exceedingly low error rates on raw transmission. Therefore, when a message is comprised of hundreds of L2 frames the most common cause of non-delivery of a message is congestion-induced drops. Message drops caused by a transmission error on even one of hundreds of frames are exceptionally rare.

With unicast delivery, the transport protocol acknowledges each packet within the overall message (typically only sending the acknowledgement for every other packet). However, typical point-to-point transport protocols negotiate a packet or byte sequence number during connection establishment. It is not feasible to simply multicast a TCP packet to multiple receivers and simply collect the acknowledgements from each target because each target will have selected a different random starting sequence for itself. With TCP, for example, network elements would have to modify the TCP sequence number for each target.

Generally, multicast delivery has been limited to unreliable delivery or has relied on negative acknowledgements to allow limited retransmission requests.

The challenges of using multicast distribution for reliable delivery of bulk payload has limited deployment of multicast addressing within storage clusters to control plane functions such as node discovery, health checking and negotiating which server would be assigned to store each object. However, conventional unicast protocols have been used to reliably transfer bulk payload. As desirable as sending once and receiving multiple times would be, the conventional wisdom has been that this cannot be achieved with reliable delivery.

Splitting the traffic submitted once within the network to multiple destinations is challenging with TCP-like protocols. Either the splitter must act as a full application layer gateway, complete with providing persistent storage for all payload it has acknowledged until the gateway itself has been acknowledged by each target, or it must spoof flow control responses from the splice point such that no packet is originated until there is a window for delivery to each of the targets, and it acknowledges no packet until it has been acknowledged by all targets. Such a gateway would also have to track which targets had acknowledged a given packet and only forward retransmitted packets to those targets that had not already acknowledged it. Re-transmitting an acknowledged packet will cause the destination to conclude that its acknowledgement had not been received, from which it would infer that the network must be congested.

Advantageously, the use of multicast addressing is far simpler. At the network layer, multicast protocols are unreliable. Hence, no tracking of per-packet reception is required.

Utilizing multicast addressing allows new payloads to enter the switching fabric once, and then deliver them to N destinations. The protocol may then advantageously track the delivery of the entire message rather the tracking the delivery of individual packets. When congestion control properly minimizes the risk of congestion drops, the resulting delivery becomes reliable enough that per packet acknowledgements are no longer required. Hence, in accordance with an embodiment of the present invention, reliable delivery may be achieved using a simpler and more efficient transport protocol. In addition, the utilization of the switching fabrics buffers may be radically reduced, achieving more efficient distribution and more effective utilization of the network.

Conventional point-to-point transport protocols rely on per-packet error detection. However, with modern wired networks, applicants believe that protecting data integrity for the entire message is more effective. This is because layer 2 error checking ensures that very few packets have undetected errors, and retransmission of the entire message is acceptable when it is seldom required.

As described herein, a congestion control protocol may be designed for environments where there is no congestion on the core links and packets dropped due to transmission errors are extremely rare by avoiding congestion on the edge links to Ethernet end stations. In particular, a congestion control protocol that prevented concurrent bulk transfers to a given egress link would make it safe to transmit the entire chunk with a single ACK/NAK. Retransmission of the entire chunk would be required after an unsuccessful delivery attempt, but this is a cost easily carried if congestion drops have been avoided and dropped frames are extremely rare. The benefits of a simplified protocol, and lesser bandwidth required for acknowledgements themselves, would compensate for the extremely rare retransmission. Combined with the benefits of multicasting, such a congestion control protocol that enables coordination of bulk data transfers in a way that avoids edge link congestion-induced packet drops should generally improve overall network utilization.

Note that the ability to avoid congestion by scheduling delivery of messages at a higher layer is dependent on networking layer 2 providing some basic traffic shaping and congestion avoidance on its own.

L2 Traffic Shaping Capabilities

The presently-disclosed solution utilizes edge-based congestion control for multicast messages. To understand how edge-based congestion control can avoid congestion-based drops of the layer 2 (L2) frames, it is useful to first review the traffic shaping capabilities of advanced Ethernet switches. In relation to such traffic shaping capabilities, the following discusses a non-blocking switch, a non-blocking core, multiple traffic classes, and protected traffic classes.

1) Non-Blocking Switch

A switch can be considered to be non-blocking if it is capable of running every one of its links at full capacity without dropping frames, as long as the traffic was distributed such that it did not exceed the capacity on any one of its links. For example, a non-blocking eight-port switch could relay traffic between four pairs of end stations at full wire speed.

More usefully, each of the eight ports could be sending 1/7th of the wire speed to each of the other ports. A non-blocking switch has sufficient internal buffering so it can queue the output frames to any one of its ports. The other ports can “share” this output without having to synchronize their transmissions. If they each have a sustained rate of 1/7th of the wire capacity then the output queue for the target port may grow temporarily, but it will not grow indefinitely. There are well-known algorithms to determine the maximum buffering capacity required.

A non-blocking switch may offer service level agreements (SLAs) to its end stations that are capable of providing a sustained level of throughput to each of its ports, as long as no egress port is over-subscribed on a sustained basis. Referring now to FIG. 1, the illustrated switch provides a non-blocking switch fabric, such that a flow from X to Y cannot be adversely impacted by any flow from I to J.

2) Non-Blocking Core

A non-blocking core is a collection of non-blocking switches that have sufficient bandwidth between the switches such that they can effectively act as though they were simply a large aggregate switch.

3) Multiple Traffic Classes

Switches typically offer multiple traffic classes. Frames are queued based upon the egress port, Ethernet class of service, and other factors such as VLAN (virtual local area network) tags.

Usually these queues do not represent buffers permanently assigned to separate queues, but rather just a method for accounting for buffer usage. When a queue is assigned N buffers it does not mean that N buffers are identified in advance. Rather it means that the number of buffers the queue is using is tracked, and if it exceeds N the excess buffers are subject to being dropped.

Advanced switches are capable of monitoring the depth of queues for multiple traffic classes and potentially taking action based on queue depth (marking excessive traffic, generating congestion notifications, or simply dropped non-compliant frames). The traffic class configuration is typically a steady configuration item for any switch. Well known algorithms allow the switch to enforce that a given traffic class will be able to sustain X Gb/sec without requiring the switch to track the state of each flow through the switch.

4) Protected Traffic Classes

A Protected Traffic Class is a traffic class that is reserved for a specific use. The network forwarding elements are configured to know which ports are members of the protected traffic class. L2 frames that are marked as part of a protected traffic class, but arrive from unauthorized ports, are simply dropped. Typically switches will also block, or at least limit, relaying frames in a protected traffic class to non-member ports.

FCoE (Fibre Channel Over Ethernet) is one example of a protocol which is dependent on a protected traffic class. The protocol is not robust if non-compliant frames can be accepted from unauthorized ports.

Replicast Transport Layer

The present section details a “Replicast” transport layer in accordance with an embodiment of the present invention. In one implementation, the Replicast transport layer operates in conjunction with a distributed storage layer for a distributed object storage system. FIG. 2 illustrates the conventional model and where Replicast transport layer and distributed storage layers may be inserted into that model as “Layer 4.5” between the conventional transport layer 4 and the conventional session layer 5.

While the present section details a Replicast transport service that is intended for usage by a distributed object storage system, the specific multicast messaging capabilities provided are not constrained to support only distributed object storage. Other applications can benefit from the presently-disclosed Replicast transport services. For example, a method for replicating file system images between file servers could also use the Replicast transport services disclosed herein. One example of this would be ZFS file servers replicating the output of the “zfs send” utility.

The following Table 1 itemizes the assignment of responsibilities between the Replicast transport layer disclosed in the present section and an example distributed storage layer that may be supported by the Replicast transport layer:

TABLE 1 Division of responsibilities between Replicast transport and distributed storage layers Responsibility Layer Comment Detection of Transport A hash signature is calculated for all transmission error. transferred content. Detection of lost L3 Transport Messages with lost packets will fail the packets signature test for the complete message. Packets are sequenced within a message, allowing for checkerboard testing for reception of the complete message. Detection of lost L5 Storage The transport layer will only detect messages messages that are partially lost, not any that are completely lost. The storage layer must detect missing messages and responses. Determination of Storage The transport layer can detect whether success specific recipients successfully received a message without corruption, but it cannot determine whether the overall message was delivered to a sufficient set of recipients. Retry of L5 message Storage The transport layer detects failure of individual deliveries. The storage layer must determine when and if a given message will be retried. Pacing of Unsolicited Storage The transport layer indicates how often the Messages storage layer may transmit unsolicited messages, but it does not pace those deliveries itself. Rather it relies on the storage layer to choose which messages to submit to comply with the rate published. Congestion Avoidance Transport The transport layer works with L2 congestion avoidance techniques (such as IEEE 802.1 DCB --Data Center Bridging) protocols to provide delivery of unreliable datagrams without dropping packets due to congestion. Note that IEEE 802.1 DCB is only one mechanism for achieving drop-resistant L2 delivery that is protected from other traffic classes. Traffic Selection (i.e. Storage The primary congestion avoidance technique Shaping Storage Traffic used is to perform most bulk content transfer or Selection of content with reserved bandwidth. The transport layer when competing for enforces reservations, but the storage layer limited bandwidth) chooses which reservations to grant by determining when each storage server would be capable of doing a specified rendezvous transfer. The present invention does not specify what algorithm any storage server in the cluster will use when proposing rendezvous transfer times based upon its current workload. There are many well = - known algorithms for making such estimates, determination of which algorithms are most cost effective for which storage resources is left to each specific embodiment. Distributed Storage The storage layer determines when a Deduplication proposed transfer is not needed because the content is already stored locally. The transport layer merely relays this information. Management of Enhanced The L2 layer is responsible for protecting the bandwidth between L2 (such traffic class from other traffic. Presumably, it Traffic Classes as DCB) also protects the other traffic from the storage traffic class. Management of Transport The transport layer is responsible for bandwidth within the allocating the bandwidth provided by L2 layer storage traffic class to specific messages and transfers. Transmit at most once Transport Datagrams are transmitted once and are typically delivered to all members of the target multicast group. Datagrams cannot be delivered more than once because each L2 message is uniquely identified by source and sequence number. Further, each datagram is identified as a specific fragment of an L5 message. Packets that are duplicate receptions are discarded. Datagram sequencing Transport Unreliable datagrams are labeled as to their sequencing within an L5 message. Multicast addressing unreliable Such as UDP/IP/Ethernet or UD/InfiniBand. datagram service

Edge Managed Flow Control

The present disclosure combines the lack of central bottlenecks with the ability to factor dynamic storage-server specific metrics, such as available storage capacity, work queue depth and network congestion on the storage server's ingress ports.

An overly simplified analysis would seek to have every storage server evaluate its own suitability for storing a specific chunk, and then having the source select the number (n) of storage servers with the highest score. However, this would not scale as the total number (N) of storage servers in a cluster increased. As disclosed herein, a scalable methodology, instead, controls the total number of requests made to each storage server. Ideally, as the cluster workload grows, the number of requests per server can be held nearly constant by adding servers and network bandwidth. This will allow the entire cluster to scale in a nearly linear fashion.

The present disclosure accomplishes holding nearly constant the number of requests per server by selecting a subset of the storage servers to process requests related to any specific chunk. The present disclosure refers to this subset as the “Negotiating Group”. The Negotiating Group will select specific storage servers from the group to store the specific chunk. Generally, the number of members in a Negotiating Group should be kept stable even as the number of storage servers grows. The complexity of the negotiation process is determined by the number of storage servers in the Negotiating Group, not by the size of the entire cluster.

Referring now to Table 2, an exemplary size (n) of the Negotiating Group is that it should scale to on the order of K multiplied by Log₁₀(N) [i.e. should scale to O(K*Log₁₀(N)], where K is a function of the storage replication count, and where N is the total number of cluster members. K may typically vary from one to five. Hence, as shown in Table 2, depending on the value of K, for 100 servers in the cluster, there should be two to ten members of the Negotiating Group, and for 10,000 servers in the cluster, there should be four to twenty members of the Negotiating Group.

TABLE 2 Number of Designated Servers in a Negotiating Group for a Cluster Replication Cluster Members K = 1 K = 2 K = 3 K = 4 K = 5 100 2 4 6 8 10 1,000 3 6 9 12 15 10,000 4 8 12 16 20

In an exemplary implementation, the server performing the “put” operation for a chunk will select a set of servers from the Negotiating Group. The selection method is not dependent on a central process or bottleneck and is capable of adapting to storage server backlogs and capacity.

In an exemplary selection method, all members of the Negotiating group receive a proposal to store the new chunk (i.e. a Put Proposal) via multicast-addressed UDP datagrams, without adding extra transmission burden on the source server. The source chooses the Negotiating Group by mapping the appropriate Chunk Hash ID to a Distributed Hash Allocation Table so as to specify the membership of the Negotiating Group and identify its members. A Chunk Hash ID may be a cryptographic hash of either a chunk's payload (for chunks that hold only payload) or of the identity of the object (for chunks holding metadata). In an exemplary embodiment, this mapping is accomplished by indexing one row from a shared Distributed Hash Allocation Table. In an exemplary implementation, each chunk may have a unique identifier that effectively incorporates distributed deduplication into the distribution algorithm, making the implementation highly tailored for document storage applications. There are existing techniques that allow distributed deduplication to co-exist with the provision of cryptographic protection for document content.

It should be understood that the “Distributed Hash Allocation Table” need not be an actual table fully implemented on every node of the network. It is sufficient that each row of the table maps to a multicast address, and that the network's multicast forwarding be configured so that a multicast message will be delivered to the members of the row. Existing protocols for controlling multicast forwarding can therefore be used to implement the “Distributed Hash Allocation Table” even if they do not consider the tables they manipulate to be anything more than multicast forwarding tables.

Referring back to the exemplary selection method, each recipient of the Put Proposal calculates when and if it could accept the chunk, or whether it already has the indicated chunk. The recipient returns a Put Accept message with the appropriate indication to not only the source, but to all other members of the Negotiation Group. Limitations on the recipient's available storage that make this specific storage server less desirable as a target are reflected by making this storage server less prompt in acknowledging the proposal or in scheduling the receipt of the chunk. Additional considerations are possible to indicate that perhaps the recipient has a heavy workload and, if there are other recipients with less workload, that their responses may also be more prompt.

While the present disclosure is not necessarily limited to storage servers, in most embodiments, the storage servers will utilize the entire bandwidth available to a single reservation at a time. In accordance with the present disclosure, there is no benefit to delivering part of a chunk. Therefore, it will generally be desirable to finish each request as early as possible, even if it means delaying the start of the transfer of a later request. It is the aggregate completion times for the transfers that matters. By contrast, conventional file systems will generally seek to make forward progress for all transfers in parallel.

Upon the collection of the responses from the Negotiating Group within the timeout window, the Chunk Source decides whether to deliver the Chunk payload in order to increase the number of replicas. If so, it creates the Rendezvous Group, which is a subset of the Negotiating Group. In the exemplary implementation, other members of the negotiating group may also see this response and update their list of designated servers that hold a copy of the Chunk.

The present disclosure also provides for efficient replication of content to the Rendezvous Group by relying on the rendezvous negotiation to eliminate the need for sustained congestion control for a multicast Chunk Put or conventional point-to-point reliable transport protocols.

Exemplary Storage Cluster

FIG. 3 is a simplified depiction of chunk transmission in an exemplary storage cluster in accordance with an embodiment of the invention. As shown in FIG. 3, there is a cluster 100 of servers and clients. The servers 102 through 112 are connected to Ethernet switches 115 and 116. While several servers and two switches are depicted, an implemented storage cluster may have a multitude of servers and a larger number of switches. The switches, in turn, may be connected to each other by one or more Ethernet trunk 127. In an exemplary implementation, the switches may be non-blocking switches, and the switches together with the interconnecting trunks may form a non-blocking core.

In this depiction, Chunk A 117 is sent from user client 101 to network switch 115 and is multicast replicated to Server 103 as Chunk A 118, Server 106 as Chunk A 119, Server 112 as Chunk A 120. Chunk B 121 is sent from user client 114 to switch 115 and is replicated to Server 102 as Chunk B 122, through trunk 127 to switch 116 and then to Server 107 as Chunk B 123 and to Server 110 as Chunk B 124. At the same time Server 102 is returning Chunk C 125 via Switch 115 to client user 113 as Chunk C 126.

Serial Transmission of Chunk Copies

FIG. 4 depicts congestion on inbound links of a distributed storage system with serial transmission of chunk copies. Such serial transmission of chunk copies is utilized, for example, in the OpenStack Object Service. The servers, clients, switches and trunks of FIG. 4 may be arranged as described above in relation to FIG. 3.

As depicted in FIG. 4, we see that Chunks A1 117, A2 118 and A3 119 (all copies of Chunk A) are transmitted sequentially through the connection between the user client machine 101 and the Ethernet switch 115. From that point, Chunk A1 121 is sent to the target server 106, Chunk A2 120 is sent to a different server 103 and Chunk A3 122 to a third server 112. Similarly the chunks B1 123, B2 124 and B3 125 (all copies of Chunk B) are transmitted from user client 114 to Ethernet switch 115 in sequential fashion, even though they are all copies of the same chunk B. From that point, the B1 Chunk 126, B2 Chunk 127 and B3 Chunk 128 are sent to separate servers. In addition, the C1 Chunk illustrates that, in addition to the PUT activities for Chunks A and B, users are also performing GETs of data. In particular, the C1 Chunk 129 is sent from the server 102 to the switch 115, and then the C1 Chunk 130 is sent to the user client 113.

Relayed Unicast Transmission

FIG. 5 depicts a distributed chunk put operation using relayed unicast transmission in a distributed storage system. Such a relayed unicast put is utilized, for example, in the HDFS. The servers, clients, switches and trunks of FIG. 5 may be arranged as described above in relation to FIG. 3.

In the illustration of FIG. 5, we walk through a sequence of events. The first event is that the user Client 101 transmits the first copy of Chunk A, namely Chunk A1 117, which is received by Server 106 as Chunk A1 118. In preferred implementations, while the Chunk A1 118 is being received, the Server 106 begins a “Cut-through” transmission (illustrated here by the ingress and egress of 118 and 119 overlapping each other) to start transmitting Chunk A2 119 which is a copy of Chunk A1. Other implementations are possible, including waiting until Chunk A1 118 is completely received prior to transmitting Chunk A2 119, but are less optimal. Chunk A2 120 is received by Server 103, copied and retransmitted as Chunk A3 121 (here again illustrated by the ingress and egress of 120 and 121) and finally received by Server 112 as Chunk A3 123.

Similarly, the user Client 114 transmits the first copy of Chunk B, namely Chunk B1 124, which is received by Server 107 as Chunk B1 125. In preferred implementations, while the Chunk B1 125 is being received, the Server 107 begins a “Cut-through” transmission (illustrated here by the ingress and egress of 125 and 126 overlapping each other) to start transmitting Chunk B2 126 which is a copy of Chunk B1. Chunk B2 127 is received by Server 102, copied and retransmitted as Chunk B3 128 (here again illustrated by the ingress and egress of 127 and 128) and finally received by Server 110 as Chunk B3 129. In this case, the retransmission of Chunk B3 128 may be delayed by the transmission of an asynchronous “get” operation which requested Chunk C 130. In this way, other operations on the Servers performing “get” operations (to retrieve data upon request) may slow down the replication of packets by the Servers.

The C Chunk illustrates that, in addition to the PUT activities for Chunks A and B, users are also performing GETs of data. In particular, the C Chunk 130 is sent from the server 102 to the switch 115, and then the C Chunk 131 is sent to the user client 113.

Overview of Replicast Transport Protocol

The present disclosure provides a method of supporting effectively reliable message exchange and rendezvous payload transfers within a multicast group or subsets of the multicast group (possibly combined with an external client). An exemplary implementation of the disclosed method may be referred to herein as the “Replicast” transport protocol.

The Replicast transport protocol sends unreliable datagrams over a protected traffic class. Protected traffic classes are a known networking mechanism used in many different IEEE 802.1 protocols. One example particularly relevant for storage networking is FCoE (Fibre Channel over Ethernet). The requirements for a protected traffic class may be summarized as follows.

-   -   L2 frames are admitted to this traffic class only from         explicitly authorized end stations.     -   L2 frames are only delivered to members of the group.     -   As long as this traffic class is in compliance with a bandwidth         budget provisioned for it, its frames will not be dropped due to         congestion caused by L2 frames from other traffic classes.

Effective Reliability

A goal of the Replicast transport layer (when it is used by a distributed storage application) is to enable effectively reliable transfer of chunks and associated tracking data within a storage cluster and to/from its clients. Distributed storage applications frequently need to make multiple replicas of storage chunks. Enabling an effectively reliable multicast replication may radically improve the efficiency of network utilization and the efficiency of server resources in a cluster.

The Replicast transport layer disclosed herein is optimized for networks where actual transmission errors are rare. In such networks, packets are typically dropped due oversubscription of either forwarding or receiving buffers.

Distributed storage applications supported by the Replicast transport protocol preferably may be expected to require more thorough validation of successful transfer of data than is supported by conventional point-to-point transport protocols (such as InfiniBand Reliable Connection, TCP/IP or SCTP/IP). To support more thorough validation of successful transfers, the Replicast transport protocol disclosed herein provides hash signatures for the entire chunk and self-validating tracking data which may be used to validate successful transfers. These measures allow incomplete or corrupted transfers to be detected by and reported to the upper layers. For example, a multicast transmission of a chunk may be successfully received by 5 out 7 target nodes. The question of whether that is a “successful” delivery may be properly answered at an upper layer; it is not something the transport layer can or should determine.

Congestion Avoidance

The present disclosure utilizes an assumption that the lower-layer transports (below the Replicast transport layer) provide at least minimal congestion avoidance features that can deal with short-lived congestion without dropping frames. The IEEE 802.1 Data Center Bridging (DCB) protocols are an example implementation of a suitable lower layer transport. Another goal of the Replicast transport layer disclosed herein is to further avoid congestion, particularly congestion over a sustained duration. The Replicast Transport layer strives to complement the existing lower layer solutions (such as DCB) to short-term congestion with solutions that avoid sustained over-commits of bandwidth.

Unsolicited vs. Solicited Bandwidth

The present disclosure seeks to effectively eliminate the risk of a congestion drop by tracking its own usage of unsolicited bandwidth, issuing its own reservations for solicited bandwidth, and relying on the lower transport layers to resolve very short span over-subscriptions and protect the traffic class from traffic from other classes.

Network administration will specify four bandwidth allocations for each participant in the protected traffic class:

-   -   Unsolicited inbound rate: Using known techniques, this         translates to a required amount of buffering to receive         unsolicited packets.     -   Unsolicited outbound rate: A base rate for transmission of         unreliable datagrams that have no reservation. This rate may be         adjusted dynamically by other sources of information. One source         that must be used is the number of failed deliveries on prior         attempts to transmit this datagram. This technique is known as         the Aloha back-off algorithm.     -   Reserved outbound rate: This may limit the aggregate bandwidth         of all rendezvous transmissions from this storage node. This         limit would seldom be reached, so some embodiments may omit this         from their implementation. One deployment where it would be         useful is when the same node was also originating traffic from a         different traffic class.     -   Reserved inbound rate: This node must limit the reservations it         grants so that this rate is never exceeded.

The disclosed congestion avoidance method may be, therefore:

-   1) Provision buffering for reception and in-network forward elements     adequate for both the Unsolicited and Solicited traffic. Unsolicited     traffic is subject to peaks because there is no advance permission     granted before a request is transmitted. Therefore, more buffering     is needed to support a specific bandwidth when using Unsolicited     messaging than would be required for reserved bandwidth. -   2) Limiting transmission rates of unsolicited messages so that the     probability of packet drop is low. -   3) Utilizing Aloha-style random back-offs of retransmissions of     Unsolicited messages used for requests.

Distributing and Retrieving Chunks

The presently-disclosed Replicast transport layer relies on the layer above it, a distributed storage system in one embodiment, to specify the following:

-   1) A Negotiating Group, which is a multicast group that will conduct     the negotiation to determine the Rendezvous Group, and may determine     the source for a data transfer in a get transaction. -   2) A Rendezvous Group, which is a multicast group that will receive     a data transfer. For a put transaction this group will be a subset     of the Negotiating Group. For a get transaction this group will     include the client or proxy that initiated the get transaction and     may include other members of the Negotiating Group that wish to     receive opportunistic copies of the chunk that has been requested. -   3) A base bandwidth quota for unsolicited traffic that this node may     generate to a specified traffic class. This quota is across support     for all requests. This quota may be dynamically adjusted by many     sources of information as to the congestion state of the network. At     the minimum this set must include the number of recent messages sent     by this node for which there was no timely response. It may include     other sources of network status that are correlated with the     congestion state of the network, including:     -   a) Measured queue depths on forwarding elements for queues that         support this traffic class.     -   b) Receipt of packets for this traffic class which were         explicitly marked to indicate congestion.     -   c) An increase in the one-way delay of packets for this traffic         class through the network.     -   d) Reports of congestion from other nodes participating in this         traffic class. -   4) A bandwidth for this node to receive solicited transfers. The     node will not grant reservations that exceed this quota.

Messages may be addressed to either Negotiating Groups and/or to Rendezvous Groups.

A negotiation is conducted within the Negotiation Group using unreliable datagrams sent with multicast addressing, as described in further detail below, to select a subset of those servers to which the bulk message must be delivered (or replicated at).

The purpose of the presently-disclosed transport is to deliver “chunks”, which are large collection of bytes used by the upper layer, to the Rendezvous Group negotiated in the transaction. Additionally, a set of opaque “transaction tokens” may be associated with each chunk and updated in each transfer.

Typical uses of “chunks” by a distributed storage layer would include:

-   5) Large slices of object payload, typically after compression. -   6) Metadata for versions of named objects, which will reference the     payload chunks to allow the full object to be retrieved.

The presently-disclosed transport requires each chunk to have the following naming attributes:

-   -   A Chunk ID which uniquely identifies the chunk and which will         never reference a different payload. In an exemplary         implementation, the Chunk ID must be effectively globally unique         for at least twice the lifetime that the chunk will be retained         or referenced.     -   A Content Hash ID: If the selected hash algorithm is a         cryptographic hash with strong immunity from pre-image attacks,         such as SHA-2 or SHA-3, then the Content Hash ID may also serve         as the Chunk ID. When only used to validate content the hash         algorithm merely has to be resistant to coincidental collisions.         Whether or not the Content Hash ID is used to, identify the         chunk, the Content Hash ID is used to validate the content of         transmitted chunks or chunks retrieved from persistent storage.

In an exemplary implementation, the Chunk ID must have a uniform distribution so that it can efficiently index locally retained chunks on storage servers.

In the preferred embodiment, the Chunk ID is always the Content Hash ID. Cryptographic hash algorithms always provide a uniform distribution.

A chunk may also have a Name Hash ID. The upper layer (for example, a distributed storage layer) may name some chunks that are used to store the root of metadata for a version of an object within the storage system and may also have a name that can be used to retrieve the chunk object. The Name Hash ID may be an additional partial identifier for such chunks (where the addition of a version identifier is required to form a complete additional identifier).

Distributed Gets and Puts

The common goal for the distributed get and put procedures is to use multicast datagrams sent using unsolicited bandwidth to negotiate a multicast rendezvous transfer using solicited bandwidth.

The first step is for the Client (User Client) to initiate the transaction by multicasting a request to the Negotiating Group. To put a chunk, the request that is multicast is a Multicast Put Proposal. To get a chunk, the request that is multicast is a Multicast Get Request.

Each of the recipients of this multicast request then responds to the Client (Chunk Sink for a get, or Chunk Source for a put). When getting a chunk, the response is a Get Response. When putting a chunk, the response is a Chunk Put Accept. Note that, for Multicast Get Requests, the Chunk Sink must accept each transfer from a specific source.

Once the rendezvous is negotiated, a multicast payload delivery can be initiated at the negotiated time. In either case (get or put), the rendezvous is to a multicast group, referred to herein as the Rendezvous Group. In an exemplary implementation, the Rendezvous Group is specified by the Client (Chunk Sink or Chunk Source). When getting a chunk, the Rendezvous Group will typically contain only the Chunk Sink, but may include other storage servers seeking to create additional replicas by piggy-backing on the delivery to the Chunk Sink. When putting a chunk, the Rendezvous Group is a subset of the Negotiating Group.

Lastly, when putting a chunk, a transaction closing acknowledgement is required. Note that the upper layer (for example, the distributed storage layer) which uses the disclosed Replicast transport layer is responsible for determining whether sufficient replicas have been created for a put transaction to complete, or whether the put transaction should be retried.

Also note that, when getting a chunk, the chunk may also be replicated to a volunteer storage server to provide additional replicas. The present disclosure allows for opportunistic replication of the chunks most frequently retrieved, thereby optimizing later retrieval of those same chunks.

Chunk Put Proposal—Client Consensus

FIGS. 6-8 depict steps of a client-consensus-based procedure for proposing a chunk put to a distributed storage system in accordance with an embodiment of the invention. In this client-consensus variation of the distributed put algorithm, each of the Put Accept messages is unicast to the Client (i.e. to the Chunk Source). This client-consensus-based procedure has advantages over the serial transmission procedure of FIG. 4 and the relayed unicast transmission procedure of FIG. 5. In comparison to the serial transmission procedure, congestion on inbound links is avoided. In comparison to the relayed unicast transmission procedure, contention between the relay (put) traffic and get traffic is avoided.

In the illustrations of FIGS. 6-8, we will walk through a sequence of events for a put transaction with the client-consensus procedure. Before this sequence of events, an upper layer (i.e. a layer above the Replicast transport layer) has already specified a previously-provisioned multicast Negotiating Group and a previously-provisioned multicast Rendezvous Group.

In a first step 1 shown, the Client multicasts a “Put Proposal” 1 to the Negotiating Group of Servers. Data fields in exemplary implementations of a Put Proposal message are described below in relation to FIG. 24. The Switches may make a best effort attempt to deliver a copy 1.1 of the Put Proposal 1 to every member of the Negotiating Group. Note that, as disclosed in this application, the nodes in aggregate are highly unlikely to transmit more unsolicited datagrams than the switch and receiver buffering can accommodate. Therefore, in almost all cases the Put Proposal will be delivered to the entire Negotiating Group.

Each recipient of the Put Proposal generates and sends a response in the form of a “Put Accept” message. In an exemplary implementation, the Put Accept message may be a “Not Now” message or a “Rendezvous Proposal” message. Data fields in exemplary implementations of a Put Accept message are described below in relation to FIG. 25. When generating a Rendezvous Proposal response, each server is free to consider its pending work requests, device performance history, and the desirability of accepting new content using a wide variety of algorithms. There is no need for these algorithms to be uniform amongst the servers. In other words, multiple different algorithms may be used by the servers. In the illustrated example: the Put Accept 2.1 message sent by a first Server in the Negotiating Group is a Not Now message; the Put Accept 2.2 message sent by a second Server in the Negotiating Group is a Rendezvous Proposal message; the Put Accept 2.3 message sent by a third Server in the Negotiating Group is a Not Now message; and the Put Accept 2.4, 2.5, 2.6 and 2.7 messages sent, respectively, by a fourth, fifth, sixth, and seventh Servers in the Negotiating Group are Rendezvous Proposal messages. The Put Accept 2.* (*=1, 2, . . . , 7) messages are received by the sending Client (Chunk Source).

FIG. 7 illustrates the next steps in the put process. The Client (Chunk Source) evaluates all of the “Put Accept” responses and determines whether a “Rendezvous Transfer” is required. For example, if there were already sufficient replicas of the chunk to be put, then no Rendezvous Transfer would be required.

The criteria for “sufficient replicas” can vary with the usage of the present invention. For example some users may establish a policy that their content should have at least four replicas in at least two different failure domains, while others may simply require three replicas in three different failure domains. In a preferred embodiment, this flexibility to accommodate differing policies is enabled by making these determinations in a callback function to the upper layer.

In the example illustrated, the Rendezvous Transfer 3 (including the chunk payload) is multicast from the Client to the Rendezvous Group, which is a subset of the Negotiating Group. Hence, copies 3.1 of the Rendezvous Transfer 3 are shown as being received by each Server in the Rendezvous Group. Data fields in exemplary implementations of a Rendezvous Transfer message are described below in relation to FIG. 26. In the illustrated example, the first and third storage servers in the Negotiating Group indicated in their Put Accept response that they could not accept delivery now (i.e. returned Not Now messages), and therefore did not join the Rendezvous Group. The remaining storage servers in the Negotiating Group indicated in their Put Accept responses that they could accept delivery and so became members of the Rendezvous Group.

The recipients of the Rendezvous Transfers 3.1 respond by unicasting a Payload Acknowledgement (“Payload ACK”) message to the Chunk Source. Data fields in exemplary implementations of a Payload ACK message are described below in relation to FIG. 27. In the illustrated example, the Payload ACK 4.1, 4.2, 4.3, 4.4, and 4.5 messages are sent, respectively, by the first, second, third, fourth, and fifth Servers in the Rendezvous Group. The Payload ACK 4.* (*=1, 2, . . . , 5) messages are received by the sending Client (Chunk Source).

FIG. 8 illustrates the final step in the put process. The client collects the received Payload ACKs and forwards them to the Negotiating Group in one or more Relayed ACK message. As depicted, a Relayed ACK 5 message may be multicast from the Client such that a copy 5.1 of the Relayed ACK message is received by each Server in the Negotiating Group. The Relayed ACK message informs each Server in the Negotiating Group as to which Servers of the Rendezvous Group are to receive the chunk to be put.

Chunk Put Proposal—Cluster Consensus

FIGS. 9-11 depict steps of a cluster-consensus-based procedure for proposing a chunk put to a distributed storage system in accordance with an embodiment of the invention. This cluster-consensus-based procedure has advantages over the serial transmission procedure of FIG. 4 and the relayed unicast transmission procedure of FIG. 5. In comparison to the serial transmission procedure, congestion on inbound links is avoided. In comparison to the relayed unicast transmission procedure, contention between the relay (put) traffic and get traffic is avoided.

In the illustrations of FIGS. 9-11, we will walk through a sequence of events for a put transaction with the cluster-consensus procedure. Before this sequence of events, the upper layers (above the replicast transport layer) have already specified a previously-provisioned multicast Negotiating Group and a previously-provisioned multicast Rendezvous Group.

In a first step shown, the Client multicasts a “Put Proposal” 1 to the Negotiating Group of Servers. The Switches may make a best effort attempt to deliver a copy 1.1 of the Put Proposal 1 to every member of the Negotiating Group. As with the client-consensus example, the Put Proposal will typically be delivered to each member of the Negotiating Group.

Each recipient of the Put Proposal responds by generating and sending a “Put Accept” message. As shown in FIG. 9, in this cluster-consensus variation of the distributed put protocol, each of the Put Accept messages is multicast to the other members of the Negotiating Group. As with the client-consensus variation previously described, each storage server is free to employ its own algorithm to generate its Put Proposal based, for example, upon its performance history, work queue depth, and the desirability of accepting more storage. In the illustrated example: the Put Accept 2.1 message sent by a first Server in the Negotiating Group is a Not Now message; the Put Accept 2.2 message sent by a second Server in the Negotiating Group is a Rendezvous Proposal message; the Put Accept 2.3 message sent by a third Server in the Negotiating Group is a Not Now message; and the Put Accept 2.4, 2.5, 2.6 and 2.7 messages sent, respectively, by a fourth, fifth, sixth, and seventh Servers in the Negotiating Group are Rendezvous Proposal messages. Each Server in the Negotiating Group receives the Put Accept 2.* (*=1, 2, . . . , 7) messages from the other members of the Negotiating Group.

The next steps in the put process are depicted in FIG. 10. Each member of the Negotiating Group evaluates the Put Accepts 2.* for the transaction. A consistent procedure may be applied during the evaluation by each member so as to concurrently determine which of them should take a specific action. One of various conventional procedures may be used for this purpose. For example, one compatible procedure involves electing a lead member (the leader) to be the first-listed designated member of the Negotiating Group that intends to accept the transfer. When no member intends to accept the transfer, it may be the first-listed designated member of the Negotiating Group, even though that member does not intend to accept. However selected, the selected Server in the Negotiating Group may multicast the Consensus Put Accept 3 to the Client. Hence, a copy 3.1 of the Consensus Put Accept 3 is shown as being received by the Client.

As with the Client-Consensus procedure, the selection process may accommodate a variety of user policies. The only requirement is that the evaluation procedures on the various members of the Negotiating Group do not derive solutions that conflict with each other. In a preferred embodiment, a callback to the upper layer is used to enable this policy flexibility.

At a specified time, or within a specified window of time, the Client performs the Rendezvous Transfer 4 (including sending the chunk payload) to the Rendezvous Group. Hence, a copy 4.1 of the Rendezvous Transfer 4 is shown as being received by each Server that is a member of the Rendezvous Group.

The final steps of the put process are depicted in FIG. 11. Each recipient of the Rendezvous Transfer 4.1 multicasts a Payload ACK 5.1 message to the Rendezvous Group. In addition, the previously-selected leader of the Rendezvous Group unicasts a Consensus ACK 6 message to the Client.

Chunk Put Proposal with Deduplication—Client Consensus

FIGS. 12 and 13 depict steps of a client-consensus-based procedure for proposing a chunk put to a distributed storage system with de-duplication in accordance with an embodiment of the invention.

The steps shown in FIG. 12 are similar to the steps discussed above in relation to FIG. 6. However, the system of FIG. 12 has de-duplication, and the chunk to be put is already stored on a number of storage servers in the illustrated example. In particular, the chunk to be put is already stored on the second, third, fifth, sixth and seventh Servers. Hence, the second, third, fifth, sixth and seventh Servers respond to the Put Proposal 1.1 with Put Accept messages (2.2, 2.3, 2.5, 2.6 and 2.7, respectively) that indicate that the chunk to be put is “Already Stored” at that server.

The Client (Chunk Source) receives the Put Accept 2.* (where *=1, 2, 3, . . . , 7) messages. From the number of “Already Stored” responses among the Put Accept messages, the Client is able to determine, in this example, that the chunk to be put is already stored on a sufficient number of storage servers. Hence, in this case, no rendezvous transfer is required. Since no rendezvous transfer is required, the Client may send a Relayed ACK 3 message to the members of the Rendezvous Group, as depicted in FIG. 13. The Relayed ACK message indicates to the members of the Rendezvous Group that there were sufficient replicas already stored, so no new replicas need to be created.

Chunk Put Proposal with Deduplication—Cluster Consensus

FIGS. 14 and 15 depict steps of a cluster-consensus-based procedure for proposing a chunk put to a distributed storage system with de-duplication in accordance with an embodiment of the invention.

The steps shown in FIG. 14 are similar to the steps discussed above in relation to FIG. 9. However, the system of FIG. 14 has de-duplication, and the chunk to be put is already stored on a number of storage servers in the illustrated example. In particular, the chunk to be put is already stored on the second, third, fifth, sixth and seventh Servers. Hence, the second, third, fifth, sixth and seventh Servers respond to the Put Proposal 1.1 with Put Accept messages (2.2, 2.3, 2.5, 2.6 and 2.7, respectively) that indicate that the chunk to be put is “Already Stored” at that server.

Each Server of the Negotiating Group receives the Put Accept 2.* (where *=1, 2, 3, . . . , 7) messages. In this example, from the number of “Already Stored” responses among the Put Accept messages, each Server is able to determine independently that the chunk to be put is already stored on a sufficient number of storage servers such that no rendezvous transfer is required. In this case, the leader may transmit a Consensus Put Accept 3 which is received (as Consensus Put Accept 3.1) by the Client (Chunk Source), as depicted in FIG. 15. The Consensus Put Accept 3.1 indicates to the Client that there were sufficient replicas already stored, so no new replicas need to be created.

Chunk Get—Client Consensus

FIGS. 16 and 17 depict steps of a client-consensus-based procedure for requesting a chunk get from a distributed storage system in accordance with an embodiment of the invention. Before this sequence of events, an upper layer (i.e. a layer above the Replicast transport layer) has already specified a previously-provisioned multicast Negotiating Group and a previously-provisioned multicast Rendezvous Group.

Note that, for a chunk get transaction, the specified Rendezvous Group is one that has been joined by the Client, or an agent acting on behalf of the Client. Typically, the Client (or its agent) will have previously joined several provisioned Rendezvous Groups for previous transactions and so one of these previously-joined Rendezvous Groups may be specified.

As depicted in FIG. 16, the Client may multicast, in step 1, a Get Request 1 to the Negotiating Group. The Switches of the system then forward the Get Request 1.1 to Servers that are members of the Negotiating Group.

Each Server in the Negotiating Group then generates and unicasts a Get Response to the Client in response to the Get Request 1.1. This response may be generated using an algorithm that factors in the current work queue depths, the performance history of the devices to be used, and other factors to derive its best estimate of earliest delivery time. However, there is no requirement that this algorithm be uniform across all storage servers. In other words, multiple different algorithms may be used by the storage servers. In the illustrated example: Get Response 2.1 is unicast by the first Server; Get Response 2.2 is unicast by the second Server; Get Response 2.3 is unicast by the third Server; . . . ; and Get Response 2.7 is unicast by the seventh Server. The Get Responses 2.* (where *=1, 2, 3, . . . , 7) are received by the Client.

The Client analyzes the Get Responses 2.* to determine which Server corresponds to the best response. As shown in FIG. 17, the Client then multicasts a Get Accept 3 to the Negotiating Group. The Get Accept 3 specifies which Get Response will be accepted (i.e. which Server is selected to provide the chunk). Each Server in the Negotiating Group receives a copy 3.1 of the Get Accept 3. Upon receiving the Get Accept, the selected Server may initiate a multicast Rendezvous Transfer 4 to the Rendezvous Group, which in this case consists solely of the Client. The Client thus receives a copy 4.1 of the Rendezvous Transfer 3 and so obtains the desired chunk.

Chunk Get—Cluster Consensus

FIGS. 18 and 19 depict steps of a cluster-consensus-based procedure for requesting a chunk get from a distributed storage system in accordance with an embodiment of the invention. Before this sequence of events, an upper layer (i.e. a layer above the Replicast transport layer) has already specified a previously-provisioned multicast Negotiating Group and a previously-provisioned multicast Rendezvous Group.

Note that, for a chunk get transaction, the specified Rendezvous Group is one that has been joined by the Client, or an agent acting on behalf of the Client. Typically, the Client (or its agent) will have previously joined several provisioned Rendezvous Groups for previous transactions and so one of these previously-joined Rendezvous Groups may be specified.

As depicted in FIG. 18, the Client may multicast, in step 1, a Get Request 1 to the Negotiating Group. The Switches of the system then forward the Get Request 1.1 to Servers that are members of the Negotiating Group.

In response to the Get Request 1.1, each Server generates and multicasts a Get Response to the other Servers in the Negotiating Group. This response may be generated using an algorithm that factors in the current work queue depths, the performance history of the devices to be used, and other factors to derive its best estimate of earliest delivery time. However, there is no requirement that this algorithm be uniform across all storage servers. In other words, multiple different algorithms may be used by the storage servers. In the illustrated example: Get Response 2.1 is multicast by the first Server; Get Response 2.2 is multicast by the second Server; Get Response 2.3 is multicast by the third Server; . . . ; and Get Response 2.7 is multicast by the seventh Server. Each Server in the Negotiating Group receives the Get Responses 2.* (where *=1, 2, 3, . . . , 7) from the other Servers in the Negotiating Group.

Each Server in the Negotiating Group analyzes the Get Responses 2.* to determine which Server corresponds to the best response. As shown in FIG. 19, the one Server that corresponds to the best response initiates a multicast Rendezvous Transfer 3 to the Rendezvous Group, which in this case consists solely of the Client. The Client thus receives a copy 3.1 of the Rendezvous Transfer 3 and so obtains the desired chunk.

Chunk Get—Cluster Consensus with Additional Target

FIGS. 20 and 21 depict steps of a cluster-consensus-based procedure for requesting a chunk get from a distributed storage system where an additional target is requested in accordance with an embodiment of the invention.

As depicted in FIG. 20, the Client may multicast, in step 1, a Get Request 1 to the distributed storage system. The Switches of the system then forward the Get Request 1.1 to Servers that are members of the Negotiating Group.

In response to the Get Request 1.1, each of the Servers generates and multicasts either a Get Response to the other Servers in the Negotiating Group. In the illustrated example: Get Response 2.1 is multicast by the first Server; Get Response 2.2 is multicast by the second Server; Get Response 2.3 is multicast by the third Server; . . . ; Get Response 2.6 is multicast by the sixth Server; and Get Response 2.7 is multicast by the seventh Server. In this case, the Get Response 2.7 from the seventh Server is an Additional Target Request 2.7.

The Additional Target Request 2.7 is a request for the seventh Server be added to the Rendezvous Group. Hence, the Additional Target Request creates an additional replica by “piggy-backing” on a get transaction using the client-consensus procedure. The Additional Target Request 2.7 may be generated by the seventh Server because it does not currently have a copy of the requested chunk. In other words, the Additional Target Request is effectively a Get Response that tells the other members of the Negotiating Group that this storage server cannot respond to this get request, but would like to do so in the future, so it will be subscribing to the Rendezvous Group to get a replica of the chunk.

Each Server in the Negotiating Group receives the Get Responses (including Additional Target Requests) 2.* (where *=1, 2, 3, . . . , 7) from the other Servers in the Negotiating Group. Each Server in the Negotiating Group analyzes the Get Responses (including Additional Target Requests) 2.* to determine which Server corresponds to the best response. As shown in FIG. 21, the one Server that corresponds to the best response initiates a multicast Rendezvous Transfer 3 to the Rendezvous Group, which in this case consists of the Client plus the seventh Server. The Client and the seventh Server thus each receives a copy 3.1 of the Rendezvous Transfer 3 and so obtains the desired chunk.

Exemplary Encoding Structures

This section will describe an exemplary set of packets that are one possible encoding of the operations described herein. The examples shown assume use of actual L3 multicast addresses.

FIGS. 22 and 23 depict a possible encoding of a generic “Replicast” message over L2 frames. As shown, each L2 frame may contain the standard L2 Header, L3 Header and L4 Header. Typically, these may be Ethernet, IP and UDP headers.

The Message (Msg) Sequence number would identify a unique message within the context of a source. The source would be identified by the L3 and L4 source addresses. Multipathing could associate multiple source addresses into a multipath session, but this association would not typically be re-iterated in each L2 frame.

The Fragment # indicates which L2 frame of the total sequence within a message this is. For the first fragment the following attributes would be encoded:

-   -   The total number of fragments.     -   The Message Type.     -   The Message Length

The Message Payload would then be encoded over multiple L2 frames, each with incrementing Fragment #s. In accordance with an embodiment of the invention, the Message Payload may comprise a fragment of a “Replicast” protocol message as described herein.

Finally, in the last fragment, a validator (Msg Checksum) would be included covering the entire Msg Payload, including portions delivered as Unsolicited payload as part of the setup command. This may be a CRC-32c checksum or better. Including a “Layer 5” checksum is a protection against incorrectly ordered fragments. L2 and L4 already provide protection against corrupt transmissions.

In some embodiments of the present invention, a Msg Checksum may cover only the metadata fields because the Content Hash Identifier already validates the payload.

As shown in FIG. 22, the Payload of the Unreliable Datagram may include a transaction identifier (transaction ID). The transaction ID may include sub-fields that indicate: 1) whether the message is a request, response or notification (Request/Response/Notification); 2) the source of the request or notification (Request/Notification Source); 3) a transaction sequence number (Transaction Sequence #); and 4) a sub-sequence number (Sub-Sequence #). The payload may further include an indication of which fragment of the message payload is being carried (This is Datagram #N). Finally, the payload includes the Nth fragment of the message payload.

As further shown in FIG. 22, the Payload of the Unreliable Datagram also includes the “Nth fragment of Message Payload.” In accordance with an embodiment of the invention, the Message Payload may be a Replicast message. An exemplary encoding structure for a generic Replicast message is shown in FIG. 23. Note that the exemplary encoding structure of FIG. 23 may be, in effect, inserted into the Nth Fragment of Message Payload field of FIG. 22.

The structure shown in FIG. 23 includes the following fields: a first field that indicates the opcode or message type; a second field that indicates that total number of fragments in the message; and a third field that is message type dependent. As a couple of examples, the opcode or message type may indicate whether the message is a chunk put proposal, or a chunk put accept. Other message types may be indicated, of course. The Message Type Dependent field (i.e. the third field) includes sub-fields that depend on the message type (i.e. the first field).

Exemplary message types are described below. These message types include: Put Proposals (FIG. 24); Put Accepts (FIG. 25); Rendezvous Transfers (FIG. 26); Payload ACKs and NAKs (FIG. 27); Get Requests (FIG. 28); and Get Responses (FIGS. 29 and 30).

Put Proposals

A Multicast Chunk Put Proposal would have source addresses for L2 through L4 reflecting the network interface being used to send the message. The L3 destination address would be the Multicast Address of the Negotiating Group (typically from the Distributed Hash Allocation Table). The L4 destination port would be a port number assigned for use by this protocol either by a local network administrator or a numbering authority such as IANA (Internet Assigned Numbering Authority).

FIG. 24 depicts exemplary encoding structures for chunk put proposal messages in accordance with an embodiment of the invention. The exemplary encoding structure on the left shows a structure for a named Chunk Put Proposal message, while the exemplary encoding structure on the right shows a structure for an unnamed Chunk Put Proposal message. For example, in Nexenta's Cloud Copy on Write™ object storage system (which will be commercially available from Nexenta Systems of Santa Clara, Calif.), a Named Chunk may correspond to a “version manifest” chunk, and an Unnamed Chunk may correspond to a content chunk. Note that these structures may be, in effect, inserted into the Message Type Dependent field of FIG. 23.

A multicast Chunk Put Proposal may provide at least the following information:

-   1) The Source of the Chunk Put Proposal. This may be a network     address currently assigned to the port or a permanent identifier of     the server independent of current network assigned addresses. (See,     for example, the source addresses in the L2 through L4 headers of     FIG. 22.) -   2) A Proposal sequence number that will be incremented for each     Chunk Put Proposal sent by a given source. As with all sequence     numbers used in networking protocols, it must have sufficient span     than the vast majority of sequence numbers are not currently in use.     (See, for example, the “Transaction Sequence #” and “Sub-Sequence #”     fields of FIG. 22.) -   3) An Identifier of the target Negotiating Group. (See, for example,     Target Negotiating Group in FIG. 24.) -   4) An enumerator specifying the Type of Chunk Put. This enumerator     is not intended to be meaningful to the transport layer, only to the     storage layer. For example, with Nexenta's Cloud Copy on Write™     object storage system (which is commercially available from Nexenta     Systems of Santa Clara, Calif.), the types may be Payload Chunks,     Sub-manifests and Version Manifests. (See, for example,     Opcode/Message Type in FIG. 23.) -   5) The Content Hash ID for the chunk. (See Chunk Hash ID field in     FIG. 24.) -   6) If this is a Named Chunk, the Name Hash ID. (See, for example,     Bucket Hash ID, Name Hash ID, and Unique Version Identifier under     the Named Chunk Put Proposal Message in FIG. 24.) -   7) The total length of the compressed payload that will be put.     (See, for example, “Length of non-volatile content” in FIG. 24.) -   8) The total length of the above content that will be put     immediately using unsolicited bandwidth, typically in an optional     portion in this message. (See, for example, “Length of above     included in the Put Proposal message” in FIG. 24.) -   9) The multicast address for a Rendezvous Group that will be used to     put the payload. The members of the Rendezvous Group are not     specified because they have not been selected yet. (See, for     example, the “Delivery Group” in FIG. 24.) -   10) The maximum desired delivery rate. This would typically be     expressed as the total bandwidth required, e.g. bits or bytes per     second rather than messages per second. (See, for example, the     Maximum Delivery Rate in FIG. 24.)

In the typical case, where a portion of the payload will be delivered using bandwidth from a Reserved traffic class, each recipient of the Chunk Put Proposal will respond with a Chunk Put Accept.

Put Accepts

A Put Accept is preferably addressed to the Multicast Address of the Rendezvous Group. An embodiment of the present invention may allow a Put Accept to be unicast addressed to the request sender.

FIG. 25 depicts exemplary encoding structures for chunk Put Accept messages in accordance with an embodiment of the invention. (Note that a “Put Accept” message may also be referred to herein as a “Chunk Accept” message.) The exemplary encoding structure on the left shows a structure for a Put Accept message that provides a Proposed Rendezvous. The exemplary encoding structure in the middle shows a structure for a Put Accept message that indicates Content Already Stored (for systems with deduplication). The exemplary encoding structure in the middle shows a structure for a Put Accept message that indicates Not Now. Note that these structures may be, in effect, inserted into the Message Type Dependent field of FIG. 23.

A multicast chunk Put Accept message may encode the following information:

-   1) The identity of the Multicast Chunk Put Proposal it is responding     to: the source identifier of the request and the sequence number     from that request. (See, for example, the Copy of Put Proposal ID in     FIG. 25.) -   2) The Target Negotiating Group as specified in the original put     proposal. (See, for example, the Target Negotiating Group in FIG.     25.) -   3) One of the following three responses:     -   a) Chunk already stored. (See, for example, the Chunk Accept         Message—Content Already Stored structure in middle of FIG. 25.)         In this case, redundant transmission of the chunk payload is not         required.     -   b) Put Proposal Not Accepted. (See, for example, the Chunk         Accept Message—Not Now structure on right of FIG. 25.) In this         case, the additional payload may also indicate the earliest time         when this Storage Server would want to consider a retry request.     -   c) Put Proposal Accepted. (See, for example, the Chunk Accept         Message—Proposed Rendezvous structure on left of FIG. 25.) In         this case, the additional payload may preferably indicate a time         window and data rate reserved for this delivery.

The upper layer will be responsible for processing these responses to determine whether the transfer is required and if so what the membership of the Rendezvous Group should be. For example, the acceptance criteria for an “adequate” number of Accepts (such that a transfer is performed) may be that at least one of the acceptances is from one of the “designated” servers and that a total number of servers in the Rendezvous Group is equal to (or greater than) a desired replication count. The Chunk Source may then initiate a multicast Rendezvous Transfer to the Rendezvous Group at the consensus time.

Rendezvous Transfers

FIG. 26 depicts exemplary encoding structures for rendezvous transfer messages in accordance with an embodiment of the invention. The structures depict a Rendezvous Transfer message without (on the left) and with (on the right) an Arbitrary Chunk ID.

A multicast Rendezvous Transfer message may encode the following information:

-   1) The Rendezvous Group which may be provided in the “Target     Delivery Group” field. -   2) The list of Server IDs that should be in the Rendezvous Group. A     recipient that is not in this list should leave the Rendezvous     Group. This list may be provided in the “List of Delivery Group     Members” field. -   3) The Content Hash ID of the chunk being put. This may be provided     in the “Content Hash ID of Chunk” field. In one implementation, the     Content Hash ID may be used to identify the Chunk. -   4) The Chunk ID, if different from the Content Hash ID. This may be     provided in the “Arbitrary Chunk ID” field. -   5) The delivery rate that is planned. A recipient that does not     believe it can sustain this rate should leave the Rendezvous Group     and explicitly negatively acknowledge the delivery of the chunk     (i.e. explicitly indicate that the chunk was not delivered). The     delivery rate may be provided in the “Delivery Rate” field. -   6) A set of Authentication Tokens for this Chunk. In the context of     a new Chunk Put transaction, there will be exactly one     Authentication Token. Interpretation and usage of the Authentication     Token is not the responsibility of the replicast transport layer.     The Authentication Tokens may be provided in the “Remaining Content”     field, and the length of these tokens may be provided in the “Length     of Tracking Tokens” field. -   7) The remaining payload that was not included as unsolicited     payload in the original Chunk Put Proposal. This may be provided in     the “Remaining Content” field.

Each recipient of the Rendezvous Transfer that is part of a put transaction will either acknowledge successful receipt and processing of the entire chunk with a Payload Acknowledgement (Payload ACK) message, or negatively acknowledge receipt (i.e. indicate failed reception) with a Payload Negative Acknowledgement (Payload NAK). A Payload ACK (or NAK) is also generated in response to a Put Proposal that included an entire chunk payload.

In an exemplary implementation, processing of a received chunk by the upper layer must be complete before the Payload ACK is transmitted. In addition, the received chunk must be persistently stored, or applied and the results persistently stored, before a Payload ACK is sent.

In an exemplary implementation, the Payload ACK may be sent both to the Data Source and to a multicast group of all servers that wish to track the existence of chunks mapped by a row of the Distributed Hash Allocation Table. Such a group may be a specific member of the Multicast Address Set or may be the default multicast address for the Negotiating Group.

An alternative method is to have each recipient of the Chunk Put message send just a unicast Payload ACK to the Chunk Source. The Chunk Source then prepares Relayed ACK messages summarizing one or more received Payload ACKs; these messages are sent to the appropriate multicast group.

The destination group may be the Negotiating Group itself, or it may be a companion multicast address taken from the Multicast Address Set for the Distributed Hash Allocation Table row where that member is designated for Payload ACK messages, either in general or specifically for named chunks.

Payload ACKs and NAKs

FIG. 27 depicts exemplary encoding structures for payload acknowledgement messages in accordance with an embodiment of the invention. Structures for named and unnamed Payload ACK messages are depicted on the left and right, respectively. A structure for a Payload NAK message is depicted in the middle.

The Payload ACK and NAK messages may encode the following information:

-   -   The Chunk ID that is being acknowledged. In an exemplary         implementation, the Chunk ID may be provided in the “Content         Hash ID” field, where the Content Hash ID is generated by         applying a hash function to the content of the Chunk.     -   If these are implemented, the Name Hash identifier and Unique         Version ID for this Chunk. The Name Hash identifier may be         implemented as shown in a combination of the “Bucket ID” and         “Name Hash ID” fields. The Unique Version identifier may be         implemented in the “Unique Version Identifier” field.     -   The status: successful or not. The status may be provided in by         the Opcode/Message Type shown of FIG. 23. If the status is         unsuccessful, then a specific payload NAK error code may be         provided. (See, for example, the Specific Payload NACK Error         Code in the Payload NAK Message shown in FIG. 27.) Indicating         specific reasons for a negative acknowledgement is useful for         diagnostic purposes, but is not necessary for the functionality         of the present invention.     -   When successful, the Server ID that now has this chunk stored.         The Server ID may be a network address currently assigned to the         port or a permanent identifier of the Server independent of         current network assigned addresses. In an exemplary         implementation, the source address or identifier may be provided         in the Request/Notification Source header field in FIG. 22.

When the Payload ACK was only unicast to the Data Source, the Data Source must multicast a Relayed ACK to the Negotiating Group to inform the members of the group of which servers now have this chunk stored. The Data Source may aggregate multiple Payload ACKs for the same chunk into a single Relayed ACK message.

Get Requests

FIG. 28 depicts exemplary encoding structures for get request messages in accordance with an embodiment of the invention. Structures for named and unnamed Chunk Get messages are depicted on the left and right, respectively.

The multicast Chunk Get messages may encode the following information:

-   1) Identification of the transaction:     -   a) A Source ID of the Client or its agent. This may be a network         address currently assigned to the port or a permanent identifier         of the Client (or its agent) independent of current network         assigned addresses. In an exemplary implementation, the source         address or identifier may be provided in the         Request/Notification Source header field in FIG. 22.     -   b) A transaction sequence number. For example, the transaction         sequence number may be provided in the “Transaction Sequence #”         and “Sub-Sequence #” fields of FIG. 22. -   2) Identification of the chunk desired. Depending on the application     layer this may take multiple forms. This could be any of the     following:     -   a) The exact Chunk ID of any chunk that does not have a Name         Hash ID. This Chunk ID will typically have been obtained from a         metadata chunk that did have a Name Hash ID. The exemplary         Unnamed Chunk Get Message shows this case where the chunk is         identified by the “Content Hash ID” field in FIG. 28.     -   b) The exact Name Hash ID of an Object combined with an optional         specification of a desired version. The exemplary Named Chunk         Get Message shows this case where the chunk is identified by a         combination of the “Bucket Hash ID”, “Name Hash ID” and “Unique         Version Identifier Range” fields in FIG. 28. -   3) The Rendezvous Group for this Get Request. This corresponds to     the “Delivery Group” field in FIG. 28. -   4) The maximum amount of unsolicited content that may be delivered     in each response. This corresponds to the “Maximum Immediate Content     Size per Get” field in FIG. 28. -   5) A Reception Window when the client will be ready to receive the     response. This may be the same (or very similar) information as     provided in the Put Accept message. This corresponds to the     “Reception Window” (or “Reception Window(s)”) field in FIG. 28. -   6) A maximum number of auxiliary responses that may be generated for     this request. Once a storage server is acknowledged as the responder     for this request, it may issue Get requests for up to this many     chunks referenced by the main requested chunk. For each of these     allowed auxiliary responses a separate reception window may be     specified. If not specified the delegated get requests will perform     a put transaction to the Rendezvous Group as though it were a     Negotiating Group. This corresponds to the “Maximum # of Delegated     Gets” field in FIG. 28. -   7) Optional additional reception windows that can be used for     auxiliary responses.

In the typical case there will be no Additional Target Requests generated. We will therefore first discuss the multicast Get Request without any having been generated, and leave for later the discussion of the case where additional targets are requested.

For a Get Request which specifies delivery immediately or relatively promptly (as defined by system-wide configuration), each Storage Server in the Negotiating Group possessing the chunk requested will attempt to respond to the Get Request as soon as its internal work queues allows it to. However, in accordance with an embodiment of the invention, only the first responding Storage Server will actually completely respond and deliver the requested chunk. As disclosed herein, the mechanisms to ensure that only one response is generated for each Get Request are dependent on the protocol used to implement this collaboration.

Note that an embodiment of the present invention may also define a Unicast Get Request, in addition to a multicast Get Request. The Unicast Get Request would be a Get Request sent to a specific storage server. It is anticipated that such a capability may be largely used for diagnostic purposes, as that there would be no end-user advantage to requesting a chunk be delivered by a specific storage server.

Each designated storage server will attempt to respond to a multicast Get Request with a Get Response message. The Get Responses will be collected either by the client or by the Negotiating Group, resulting in a single source being selected.

Get Responses

FIG. 29 depicts exemplary encoding structures for get response messages in accordance with an embodiment of the invention. Structures for named and unnamed Get Response messages are depicted on the left and right, respectively.

The Get Response messages may encode the following information:

-   1) A Timestamp indicative of when the response would occur. See     “Timestamp when response would occur” field in FIG. 29. -   2) The Source ID and IP address of the responding server. The Source     ID may be provided in the “ID of storage server” field in FIG. 29.     The IP address of the responding server may be provided in the IP     header of the packet. -   3) Identification of the Multicast Get Request that is being     responded to, and which portion of the response this is: the primary     content; or the ordinal offset of which referenced chunk is being     transferred. The Get Request may be provided in the “Copy of Get     Request ID” field in FIG. 29. -   4) The Rendezvous Group ID that will be used (which is repeated from     the Get request). This may be provided in the “Delivery Group” field     in FIG. 29. -   5) The rate at which the chunk will be transmitted. This may be     provided in the “Delivery Rate” field in FIG. 29. -   6) The Content Hash ID of the chunk it will deliver, and if this is     a named Chunk, the Name Hash ID and unique version identifier of the     chunk. The Content Hash ID may be provided in the “Content Hash ID”     field in FIG. 29. The Name Hash ID and unique version identifier may     provided in the “Bucket ID,” “Name Hash ID” and “Unique Version ID”     fields for the Named Chunk Get Response Message in FIG. 29. -   7) If the requested chunk is too large, an error message may     indicate this problem and specify the actual metadata and payload     lengths (see below description of an error Get Response message).     Otherwise, any immediate portion of the requested content and the     length of the immediate portion may be provided in the “Immediate     Content” and “Immediate Content Length” fields in FIG. 29. Note that     the entire content requested may consist of: a) the metadata and     integrity checking data; and b) the payload. The “Content Length”     field in FIG. 29 may indicate the combined length of the entire     content requested.

In some embodiments, a storage server may respond with a Content Not Immediately Available message that indicates that it cannot return the content requested until at least a specified time. This would typically be due to migration of the requested chunk to offline storage. Issuing such a response may indicate that the process of moving the requested chunk back to online status has been initiated. However, the request should be re-issued at some time after the time indicated.

In an exemplary implementation, each respondent only sends the first datagram in the response. This response is sent using unsolicited bandwidth. The balance will only be transferred once the specific server has been selected to perform the rendezvous transfer using reserved bandwidth.

Unless the entire response fits in a single datagram, a single responder must be selected to complete the transfer. This may be the primary member of the Negotiating Group offering to deliver the content. This selection is multicast as a Multicast Get Accept message to the Negotiating Group, and the selected server will then begin the transfer. The selected rendezvous transfer is then initiated using reserved bandwidth by the selected storage server to the Rendezvous Group specified in the original Multicast Get Request.

Error Get Response Message

FIG. 30 depicts exemplary encoding structures for an error Get Response message in accordance with an embodiment of the invention. As shown in FIG. 30, an “Error Code for Chunk Get Response Message” may be provided in this error message.

Volunteer Servers

Volunteer Target Servers may issue Additional Target Requests to the Negotiating Group. These messages request that the Volunteer Target Servers be included in the Rendezvous Group as well. When a multicast protocol is used with IGMP (Internet Group Management Protocol) control, this is actually a notification that the additional target will have already joined the Rendezvous Group by the rendezvous time. The additional target merely has to attempt collection of the rendezvous transfer, and saving the chunk if it is received successfully with the payload matching the signature provided. With a multicast protocol not controlled by IGMP, the server selected to perform the Rendezvous Transfer adds the server to the Rendezvous Group as provided by that alternate protocol. Again, the target merely has to collect the chunk on that multicast group, and save the chunk locally if successful. When a unicast chain simulates multicast, the first responding storage server must add the server to the list. This will result in the same chained delivery as described for the put algorithm, except that no Payload ACK message is required.

Expedited Limited Joins

The present disclosure describes a method where multiple servers join a Rendezvous Group and then depart it for each put transaction. Additional targets also join and then depart a Rendezvous Group for each delivery.

The set of servers that is allowed to join these groups dynamically is preferably restricted to those that already belong to an enabling cluster-wide group. This allows embodiments to bypass potentially excessive overhead associated with normal management plane operations.

When IGMP controls group membership, then during a put transaction an individual storage server will:

-   7) Join the group after sending a Chunk Put Accept. -   8) Depart the group when the first of the following events occur:     -   a) It sends a Payload Ack for this transaction. Note that any         storage server has the option to conclude that a transfer will         not complete successfully and send a Payload NAK without waiting         for the transfer to complete. Detection of gaps in the sequence         of received datagrams is one reason for reaching this         conclusion.     -   b) It receives a Rendezvous Transfer which does not list the         storage server as a recipient.     -   c) It receiving a Rendezvous Transfer which specifies a transfer         rate in excess of what the storage server estimates it will be         able to sustain.     -   d) It receives a message from that sender that explicitly aborts         the Rendezvous Transfer.

Mechanisms for Reliable Multicast Payload Delivery

Although a multicast protocol is typically perceived as an unreliable protocol, the number of congestion drops or mis-delivered packets on most wired LANs is extremely small. Since multicasts still have a non-zero probability of not reaching all of the target servers, the Replicast transport protocol provides mechanisms that add reliability to an inherently unreliable protocol, but without the amount of overhead of “reliable” transport mechanisms, such as TCP/IP. These reliability mechanisms are described below under: 1) Chunk Source Responsibilities; 2) Distributed, Reliable Chunk Replication; 3) Requirement for Keep-Alive Service; 4) Lower Layer Tranport Protocol; 5) Contention for Unsolicited Bandwidth; 6) Storage Server Queues; and 7) Detection of Non-Compliant Core Network.

1) Chunk Source Responsibilities

One aspect of the “reliability” of the presently-disclosed Replicast transport is that it does not depend on the original chunk source to ensure that all of the copies are made. The chunk source is only responsible for ensuring that the minimum set of replicas are created (with at least one copy on a designated server) before the transaction can be declared complete. Once those copies are guaranteed, then control is returned to the user application that created the object. More replicas will be created, as needed, automatically. Replication of chunks in accordance with the presently-disclosed Replicast transport is an ongoing process that does not necessarily have an end point.

2) Distributed, Reliable Chunk Replication

Now we describe a distributed mechanism for reliability. In an exemplary implementation, each of the Chunk copies keeps a list of the designated destinations for the chunks. (Note that the original source server may be one of these chunk copies that is not a designated copy.) The size of this list is controlled by the replication count for the object, which can also vary by object. If any of the destinations does not yet have a copy of the chunk, then the server holding the chunk wants to replicate the chunk at one or more of the destinations. This distributed replication is an ongoing responsibility of each chunk server. The replication retries are a continuous background task for the storage servers. However, to avoid network congestion, each of the retries may be done on a random interval basis, analogous to the CSMACD collision detection and retry mechanism. In this manner, the replication task may be spread across many different servers and not left to a single source server.

This proclivity to replicate exists for each storage server regardless of its retention of a list of known other replicas. Retaining such data enables optimization of the replication process, but is not necessary for its correctness.

This same mechanism for performing replication is used whenever servers join or leave the ring of servers. Each chunk server is continuously updating the list of servers that have copies of a chunk. If a ring membership change occurs, caused by a failed server or a partitioned network, there will typically be insufficient replicas of chunks previously assigned to the now missing servers. It will then be the responsibility of all chunk owners to attempt to replicate these chunks. It is not necessary for every server to have an accurate count of the number of replicas. If a given server's estimation is low it will attempt to replicate the chunk, and discover that there are sufficient replicas. Some packets are exchanged, but there is no unnecessary rendezvous transfer.

In preferred implementations, the multicast addressing is used for payload delivery as well as for “unsolicited commands” that carry a payload, rather than negotiating for a time to send the payload. Preferred implementations may ensure that the network switch has been provisioned so that the bandwidth allocated for storage and “unsolicited” traffic is non-blocking up to a pre-determined limit and that the network will not experience congestion as long a s the process of reserving payload transmission does not exceed that threshold. This helps to ensure that the “unreliable” multicast is actually quite reliable since it does not run the risk of data loss due to network congestion.

While all commands and payload transfers may be retried, they can avoid the need to retransmit by: protecting the storage traffic from general purpose traffic not complying with these special rules; limiting the bandwidth for unsolicited transmissions to a provisioned rate; limiting the bandwidth for reserved transmissions to a provisioned rate; and only utilizing the reserved bandwidth in accordance with rendezvous agreements negotiated using unsolicited transmissions.

3) Requirement for Keep-Alive Service

The present disclosure generally assumes the deployment of a keep-alive service on the same set of servers. The keep-alive service will promptly detect the departure or loss of contact with any member and have provision for the authenticated joining/re-joining of members. Further, it is assumed that the keep-alive service will determine the round-trip time for each of the storage servers.

4) Lower Layer Transport Protocol

The present disclosure generally assumes a lower layer transport service to provide unreliable datagram service with multicast or unicast addressing. There are also specific congestion control assumptions made about the lower layer protocols. The Replicast transport protocol will function correctly even if these services are not provided, but may exhibit undesirable performance characteristics. For example, the presently-disclosed implementation generally assumes that delivery of unreliable datagrams will be effectively drop free if the nodes comply with the provisioned bandwidth limits. The throughput could fall below what would be achieved with conventional solutions if this is not true, but errors will still be detected and properly dealt with.

Specifically the lower layer transport is expected to:

a) Utilize a protected L2 capacity, such as would be provided by the IEEE 802.1 Enhanced Transmission Service (ETS). Specifically, insertion of L2 frames for this class of service must not be allowed from unauthorized sources. L2 frames that are compliant with the negotiated rate for this traffic class must not be at risk of being dropped for lack of network buffering because of L2 frames submitted for another traffic class.

b) Send messages that are each comprised of multiple unreliable datagrams to a small defined group of target addresses where each frame within the message is labeled as to which message it is part of and which portion of the message the frame encodes. Placement of payload from each unreliable datagram should be possible even when received out of order.

c) Be able to define a multicast Rendezvous Group as a subset of an administratively configured group. Methods for implementing multicast addressing include:

i) Native L2 or L3 multicast addressing capabilities. Both IP and InfiniBand support multicast addressing.

ii) Broadcasting messages on a virtual network (VLAN, VXLAN, etc.) where only the members of the multicast group have access to the virtual network.

iii) Use of a custom L4 protocol.

d) Be able to define a multicast Rendezvous Group as a subset of another group created by this transport service.

e) Additionally, take other actions to prevent drop of L2 frames due to temporary network congestion, such as IEEE 802.1 Priority Flow Control (also known as “Per Priority Pause”).

Additionally, the receiving stack should be able to discard packets that are duplicates of content already provided to the storage layer.

On IP networks, both the UDP and SCTP transport layers can be used. UDP is the preferred embodiment because it is simpler. SCTP adds multi-homing and multi-pathing, but does so at the expense of needing to maintain reliable associations between SCTP endpoints. On InfiniBand networks, the Unreliable Datagram (UD) transport would be the preferred implementation.

The transport layer is also traditionally responsible for ensuring error free delivery. The presently-disclosed technique assigns that responsibility to the storage layer, which validates the Content Hash ID on all transfers.

One feature of the disclosed transport layer is to only enable allowed traffic. L2 frames for the storage traffic class may only be accepted from authorized end stations. To preserve network security, data sources may only create multicast groups whose membership is a subset of a pre-existing group. Network administrators frequently must support multiple different groups of users, frequently called tenants, on a single network. The service providers must be able to ensure each tenant that there their traffic will not be delivered to ports controlled by other tenants. Network administrators typically need to configure port groups so that network traffic for different tenants cannot mix without going through a router that enforces filtering rules.

There are three approaches to providing the desired transport services:

a) Use existing multicast protocols such as IP multicasting and the Internet Group Management Protocol (IGMP). This approach has the benefit of being standards based, but may require an implementation to impose a minimum delay before payload transmission to allow for the latency required by the IGMP protocol.

b) Use a custom control plane that is optimized to establish existing data-plane control data to use multicast addressing and/or VLANs to achieve the desired group forwarding.

c) Use a custom L3 routing protocol to establish the desired destinations for each packet. The custom L3 routing would dictate which L3 routers each packet was to be delivered to, and the full set of L2 destinations that each router must deliver the packet to.

With the standard IGMP approach, each host may join or leave any multicast group, identified by a multicast IP address. IP datagrams sent to a multicast IP address will be best effort delivered to all members of the group.

The IGMP method requires each target to control its membership in each group. The other solutions involve customizing other methods already supported by network elements for delivering frames to a controlled set of destination links. For all of these methods, the sender must first invoke a designated module to reconfigure the switch forwarding tables as required. Methods for implementing this include, but are not limited to, OpenFlow modules and vendor-specific Switch control plane plugins.

Alternatively, a custom control plane can directly edit existing data-plane forwarding control data to effectively emulate multicast delivery with sender or push based control. This solution works when the forwarding elements have updatable behavior. This can include a custom control-plane module, such as defined by Arista Networks of Santa Clara, Calif. for their switches, or by the Open source OpenFlow standard.

The first custom control plane method is to define a Port Group on an actual or virtual network switch. Any broadcast message sent on one of those virtual ports will be delivered to all other virtual ports of the group. Port Groups are typically limited to ports on a single switch. When the ports are on multiple switches, some form of packet or frame labeling is typically required.

One method of doing so is the 802.1 Virtual LAN (VLAN). Ethernet frames tagged with a VLAN are only forwarded to ports belonging to that VLAN and to switches as needed to reach those ports. Any broadcast message sent from one of the virtual ports will be delivered to all other virtual ports in the VLAN.

There are other protocols which that provide the same functionality as a VLAN, but without the limitation on the number of VLANs. One example of such as protocol is the VXLAN (Virtual eXtensible Local Area Network) protocol.

The last method is to define a custom L3 header which that establishes both the set of L3 routers that this packet must be delivered to, and then the L2 destinations at each of those destinations.

5) Contention for Unsolicited Bandwidth

The bandwidth reserved for unsolicited transmissions cannot be guaranteed to be adequate for a spike in demand. With the reserved bandwidth there will be at most one participant attempting to transmit to any given target at any given time. However, the capacity reserved for unsolicited transmissions is based on an estimate, not on reservations. Estimates can be low. Therefore, collision drops are possible.

The L2 network may be configured to use technique such as Priority Flow Control (PFC) to minimize drops caused by very short over-demand on the unsolicited capacity. Most L2 networks will allow traffic to exceed the reserved rate for unsolicited traffic provided that it does not require dropping frames from non-storage traffic. These techniques can make rare drops caused by over-subscribing of the unsolicited capacity even more rare, but they cannot totally eliminate the risk.

Therefore, all unsolicited requests are acknowledged. An unanswered request is retransmitted. Because each unsolicited request is uniquely identified by its source and a sequence number from that source, all recipients of a retransmitted request can recognize it as one they have previously processed (which can happen when it was their response that was lost, rather than the original request). Redundant requests can be processed by replaying responses from a response cache.

Even with the potential need to retransmit requests and responses, the presently-disclosed transport protocol can outperform conventional solutions using TCP/IP or other reliable point-to-point transports. A spike in the number of requests would have also produced a spike in the number of connection requests in a TCP/IP solution. The TCP/IP SYN requests (to establish connections) would have failed just as often, and needed to be retried as well. While the retries would have been from the kernel, rather than the application layer, there would still need to be more round-trips with a reliable transport.

With the presently-disclosed transport protocol, exchange of unsolicited messages requires two messages. With reliable point-to-point transports there would need to be three or four packets required to establish the reliable connection, then the exchange of application layer messages, following by an eventual TCP tear-down of the connection.

The network should be configured so that the buffering available for unsolicited requests in both the forwarding elements and the receiving nodes is sufficient for all but the most extreme peaks of traffic. Well-known conventional solutions can make these exchanges just as reliable as reliable transports with less demand on network resources.

The present disclosure also relies upon the Replicast transport layer pacing its upper layer in some manner that limits the aggregate number of unsolicited datagrams to comply with the available buffering. The most minimalistic implementation of this is simply applying an Aloha-style random back-off for retransmission of unacknowledged request datagrams. When network congestion is high more requests will be unacknowledged, which is sufficient information to spread the retransmission over a wider time span. This effectively lowers the aggregate transmission rate.

However, it should be understood that the method used to pace the upper layer is not constrained to a conventional delay on the transmission of an already submitted datagram. Embodiments of the present invention may use a variety of techniques to refine the estimation of contention for the unsolicited bandwidth. Furthermore, this pacing information may be simply shared with the upper layer so that the upper layer may select what datagrams it wants to submit. There is no constraint to merely time the delivery of already submitted datagrams.

6) Storage Server Queues

In an exemplary implementation, the following types of storage traffic may be treated differently:

a) Messages carrying Commands and Responses would use an Unsolicited traffic class and be queued to a short command/response queue on each Storage Server. Obtaining an Ethernet traffic classes for both Unsolicited and Solicited storage traffic will not always be feasible. In many embodiments, a single Ethernet traffic class will be used combined with assigning UDP port numbers to either Unsolicited or Solicited inbound queues.

b) Messages carrying Solicited Payload could use a Solicited traffic class and be steered to a payload queue on each Storage Server, or be differentiated solely by the destination UDP port number.

7) Detection of non-compliant core network

The presently-disclosed transport protocol relies on the core network to deliver multicast packets only to the edge links identified by the multicast group as currently tailored. An implementation may monitor this compliance, preferably independently but possibly as part of processing incoming Ethernet frames. Excessive delivery, such as would be caused by inadequate forwarding tables resulting in excessive flooding of Ethernet frames out of all non-originating ports, indicates that use of the presently-disclosed protocol should be suspended with conventional TCP-like protocols being used instead.

Alternative Implementations and Special Notes

This section describes alternative implementations and other aspects of the presently-disclosed transport protocol.

1) Variations in Participation by Negotiating Group Members

The Negotiating Group identifies the set of storage servers that should receive get or put requests for those chunks. However, not all members of this group need necessarily be equal.

For example, when IGMP is used to control multicast groups, storage servers that have access to a parent VLAN may be allowed to join the multicast group and thereby become an “associate” member of that group. These “associate” members will receive Put Proposals and Get Requests, but they are not relied upon to provide long-term persistent storage of chunks. They are not on the designated list for the group, and, therefore, will not count towards certain minimal retention requirements.

With sender-controlled memberships, these additional members would be listed as special members of the Negotiating Group. This will require representation in whatever table or datastore used by the upper layers to selected Negotiating Groups.

2) Simulated Multicast Rendezvous

Alternative embodiments may implement a rendezvous transfer using chained point-to-point transfers. These transfers would still be done with a nominally unreliable transport, such as UDP/IP or InfiniBand Unreliable Datagrams (UD). To implement a unicast chain delivery, each storage server will do the following steps:

a) Initiate a unicast point-to-point transfer (typically UDP/IP) to a port or service indicator on the Client/Agent. The client, or agent, will explicitly send a delivery abort response back to the sender for all but one of the transfers. Delivery of the chunk will be discontinued when an abort is received. Implementations may choose to slightly delay the second frame of a response to allow any abort message to be received.

b) Otherwise, deliver the chunk to the Client/Agent over the point-to-point transfer with a Target list consisting solely of the client/agent.

3) Delegated Get Request

In one embodiment of the present invention, the process of getting an object is further optimized for distributed object storage systems which store metadata for a version of an object separately from the payload. The root chunk of an object (also called the “version manifest” or metadata) contains references to the chunks/blocks.

In a default embodiment, the issuer of a Get Request would obtain the version manifest chunk, and then issue Get Requests for the referenced payload chunks. This pattern is used in both pNFS (parallel NFS) and the Hadoop Distributed File System (HDFS).

In an optimized embodiment, the storage server delivering the version manifest chunk may originate Get Requests for a specific number of the initial payload chunks referenced by the version manifest. These requests specify the originator of the Get Request as the target by using the same Rendezvous Group.

Each L5 message for these auxiliary deliveries specifies a sub-sequence number that allows the Chunk Sink(s) to determine which payload chunk is being delivered. The original Get Request specifies the maximum number of auxiliary deliveries it will accept and a delivery window for each.

4) Alternative Delivery Patterns

There are several patterns detailed in this disclosure where the same information is relayed to bother the Rendezvous Group and the Negotiating Group. It should be understood that in all cases any of the following implementations are equally valid:

-   1) The information is sent to the Rendezvous Group. The transaction     originator then relays this information to the Negotiating Group     either as an extra message, which may consolidate multiple     responses, or by including this information in the next message it     would send to the same Negotiating Group. -   2) The information is sent to the Negotiating Group, which then     determines what the consensus is before sending a single response to     the Rendezvous Group. -   3) The information is sent to both groups in parallel. This option     is particularly attractive with a custom L3 protocol. -   4) The information is sent to both groups in parallel under specific     scenarios where the implementation has determined that the improved     latency offered by dual forwarding this specific information     justifies the additional network traffic. Such determinations may be     dependent on implementation or even site-specific factors.

5) Alternative Indefinite Reservations

In an alternative embodiment of the present invention, it may be advantageous to recognize when the storage cluster consists of a relatively small number of storage servers and a similarly small number of clients.

When this condition is recognized it may be advantageous for storage servers to grant permanent bandwidth reservations to the clients, and credits for creation of chunks up to a certain aggregate size.

When such a reservation is granted, the clients would be able to dispense with making a Put Proposal, simply assume the Rendezvous Group was identical to the Negotiating Group and immediately put the chunk using the unsolicited protocol.

When the number of storage servers increased the system would shift to normal operations and require the handshake to reserve protocol.

Upper Layer Decision Making

The transport protocol disclosed includes decision making performed by the upper layer. This is the layer above the transport layer. In one embodiment, the upper layer is a storage layer.

For get transactions, the upper layer (of the client in a client consensus embodiment, or of the servers in the negotiating group in a cluster consensus embodiment) is responsible for evaluating all Get Responses to determine which offering server will be the source of the transfer, and the time of the transfer (within the range offered). The source and time of the transfer may then be provided in a Get Accept message. In one simple embodiment, the transfer source may be selected from the offering servers by a randomized selection technique. In another embodiment, the transfer source may be selected from the offering servers by a procedure which takes into account earliest time for transfer indications obtained via the Get Responses and may also take into account the location of the offering servers within the network topology. In one example, offering servers closer to the requesting client in the network topology may be favorably weighted.

For put transactions, the upper layer of the servers in the negotiating group is responsible for evaluating all Put Proposals to determine whether a rendezvous transfer is needed, and if so, at what time and at what rate. The time and rate of the transfer, if needed, may then be provided in a Rendezvous Proposal message to the initiating client (in the client consensus embodiment) or to the other servers in the negotiating group (in the cluster consensus embodiment).

The upper layer is also responsible for determining when each server will offer to do a receive or transmit. This determination may start with the best estimate that the server can make as to the earliest time when the server can be confident that the transfer can occur. Determining the best estimate for the earliest time may involve scheduling of network bandwidth on the local links for the server (to find the earliest time when the link will be free for reception or transmission of the chunk) and of its input/output to persistent storage (since there is little benefit of receiving data that cannot be written to disk until much later because other writes are already committed and/or because of required head movement for traditional hard disk drives).

The algorithm used to make these scheduling estimates may be dependent on the relative speeds of the network and storage devices, and on the resources available to make the estimations. Embodiments of the present invention do not necessarily require any specific algorithm be implemented, although it is preferable that the estimation be as good as possible with the available resources.

A comparison can be made with a free market system. Approaching an optimum balancing of supply versus demand is not dependent on every participant analyzing the market perfectly, just that generally participants are trying to optimize their decisions.

Example Computer Apparatus

FIG. 31 depicts a simplified example of a computer apparatus 3100 which may be configured as a client or a server in the system in accordance with an embodiment of the invention. This figure shows just one simplified example of such a computer. Many other types of computers may also be employed, such as multi-processor computers.

As shown, the computer apparatus 3100 may include a processor 3101, such as those from the Intel Corporation of Santa Clara, Calif., for example. The computer apparatus 3100 may have one or more buses 3103 communicatively interconnecting its various components. The computer apparatus 3100 may include one or more user input devices 3102 (e.g., keyboard, mouse, etc.), a display monitor 3104 (e.g., liquid crystal display, flat panel monitor, etc.), a computer network interface 3105 (e.g., network adapter, modem), and a data storage system that may include one or more data storage devices 3106 which may store data on a hard drive, semiconductor-based memory, optical disk, or other tangible non-transitory computer-readable storage media 3107, and a main memory 3110 which may be implemented using random access memory, for example.

In the example shown in this figure, the main memory 3110 includes instruction code 3112 and data 3114. The instruction code 3112 may comprise computer-readable program code (i.e., software) components which may be loaded from the tangible non-transitory computer-readable medium 3107 of the data storage device 3106 to the main memory 3110 for execution by the processor 3101. In particular, the instruction code 3112 may be programmed to cause the computer apparatus 3100 to perform the methods described herein.

Summary of Features and Advantages of Multicast Transport

The presently-disclosed transport protocol allows the set of storage servers providing persistent storage for a chunk to be selected from those that can store the chunk most promptly, rather than arbitrarily selecting a set of storage servers without regard for network traffic or server workloads.

In conventional solutions, selecting storage servers based upon their current loads was limited to systems with a centralized metadata system, such as HDFS and pNFS. Other previous solutions use consistent hashing algorithms to eliminate the central bottleneck, but are then incapable of considering dynamic factors such as queue depth.

The presently-disclosed transport protocol allows the Chunk Source to select the optimum set of storage servers to take initial delivery of a chunk from amongst the Chunk Put Accept responses collected to a multicast Put Proposal. Centralized metadata solutions can only perform this optimization to the extent that the central metadata server is aware of the resource status of every storage server in the cluster. Existing consistent hash algorithms can only adjust boundaries for longer term changes in the distribution. Any change in the distribution of chunks requires moving previously committed chunks. Only major changes in the distribution can justify the migration costs of adjusting the distribution.

The presently-disclosed transport protocol allows the initial source of a chunk to select the initial Rendezvous Group. In selecting the initial Rendezvous Group, the source server has many options to influence the members of the group. Some of the considerations may include, spreading replicas across failure domains, selecting destinations that have the largest amount of free space, destinations that have a best rating (combination of CPU power and memory space available, e.g. Windows Experience Index) as well as other factors that can vary dynamically, including the speed, number and/or cost of the link(s) between the source and the sink.

The presently-disclosed transport protocol also allows storage servers with excess capacity and currently low work queues to volunteer to provide additional replicas of chunks. In fact, many storage systems have the notion of “hot stand-by” drives that remain powered up, but idle, to step in when an existing drive fails. With an exemplary implementation of the present invention, these hot stand-by drives can be used to perform a performance enhancing “volunteer” duty to hold volatile extra copies of objects. Clients can find these additional replicas using the Negotiating Group. The Negotiating Group also enables collaboration within the group can be found by clients seeking those chunks and/or when replication of those chunks is required due to the loss of an existing storage server (or the additional of a new storage server).

The presently-disclosed transport protocol also allows for dynamic adjustment of a Distributed Hash Allocation Table to dynamically load-balance assignment of responsibilities among the storage servers. The present disclosure also allows for alternate strategies, such as holding new servers in reserve to replace failed or to offload overloaded servers. Prior solutions could only provide this type of flexible resource assignment by centralizing the function of the metadata server.

The presently-disclosed transport protocol also provides for improved utilization of network bandwidth and buffering capacities. Bandwidth capacities may be quoted for network elements as though they were reserved. However, this is not how network elements actually operate. Buffers are not pre-enumerated for different classes of service. They come from a common pool. Stating that the network element has a queue for up to 40 Ethernet frames in Class X does not mean that there are 40 buffers pre-allocated for that purpose. Rather, it means that after 40 frames are queued for Class X, further frames for Class X may or will be dropped, and that no frames for a different Class that is below its quota will be dropped because an excessive number of frames for Class X were queued.

This can be thought of as a reservoir with controlled ingress and egress rates. As an analogy, it may be known that, in aggregate, 30% of the water in the reservoir came from river W, but that does not mean that it is easy to find the specific drops in the reservoir.

With an exemplary implementation of the presently-disclosed transport protocol, the time that copies of a given chunk will be in network element buffers is greatly reduced. With unicast protocols, a buffer will be required for the reception time, queued time and transmit time for each of the three copies. In contrast, with the presently-disclosed protocol, a single buffer will only be held for the reception time, the longest queue time of the three copies, and the transmit time. While this will be more than one-third of the time that buffers will be held for the unicast protocols, it is still a considerable improvement with a replication count of three. Higher replication counts produce even more dramatic improvements.

Even if there are no changes in the class of service traffic shaping for any of the Ethernet priorities, this now unused buffer capacity can enable more Unsolicited and more non-storage packets to be successfully delivered over the same local area network than could have been delivered had a unicast delivery strategy been used. Less buffering also means prompt transmission, which will improve average delivery times.

In summary, the presently-disclosed transport protocol provides for effectively reliable delivery of multicast chunks (and associated tracking data) using unreliable datagrams. It does this by effectively eliminating the risk of congestion-based drops. It extends enhanced L2 techniques, such as IEEE 802.1 DCB (DataCenter Bridging) protocols, by dynamically allocating edge bandwidth between unsolicited and solicited transfers. Each transfer is paced so as to avoid sustained over-subscription of network capacity, which the L2 techniques such as DCB cannot solve.

II. Scalable Object Storage Using Multicast Transport

In accordance with an embodiment of the invention, an object storage system and method uses multicast messaging to perform replication of chunks that encode object metadata and data within distributed object storage systems by using multicast messaging to notify assigned servers and distribute chunk copies for storage and replication. Reliability may be advantageously achieved by collaboration between the presently-disclosed object storage layer and the multicast messaging layer described in detail above.

Metadata and data are frequently handled differently in conventional solutions, but there are still fundamental similarities in the handling of metadata and data. A preferred embodiment of the presently-disclosed object storage layer handles metadata and data in a unified manner. However, uniform handling is not a necessity for the present invention. In this disclosure, the term “chunk” can refer to any subset of the metadata or data for a version of an object, without regard to how uniform or divergent the handling of metadata is from data in a specific storage system.

Multicast transmission, which performs the sending of data once to be received by multiple receivers, is traditionally viewed as being inherently unreliable. The presently-disclosed object storage layer provides effective reliability in collaboration with a transport layer on top of conventional unreliable multicast messaging. This collaboration fulfills the classic role of the transport layer. This collaboration enables avoidance and/or recovery from congestion drops in the network and also provides for recovery from non-congestion drops as well.

Conventional multicast transmission is deployed where there can be a very large number of recipients, making normal flow or congestion control unworkable as a solution. In contrast, an embodiment of the presently-disclosed object storage system anticipates using a small number of recipients (such as, for example, less than one hundred recipients) so that flow control is manageable. An additional aspect of the presently-disclosed object storage system is that due to the redundancy of chunk replicas, the system is safe when a minimum number of copies have been made, and the storage system can be tolerant of jittered delivery.

The presently-disclosed object storage system uses multicast addressing to resolve issues such as assigning which storage servers will hold which chunks, and then performs a negotiation to select a rendezvous time window for a subset of the assigned servers. Multicast messaging is then used to enable efficient, reliable and eventually consistent distribution of chunks.

Layering

The presently-disclosed object storage system is a distributed object storage system that relies on specific multicast messaging capabilities being provided from a transport layer. However, the separation between the transport layer and the storage layer is not conventional.

These two layers occupy a layer above the conventional transport layer (“L4”) and below the session layer. Other protocol suites occupying this layer have been referred to as “L5” protocols, even though strictly speaking they are below the Session Layer (which is the correct definition of Layer 5). The primary examples of “L5” protocol suites include iSCSI and RDMA over IP (WARP).

The presently-disclosed storage layer relies on a transport layer at that same layer. Together, the presently-disclosed storage layer and its supporting transport layer may be referred to as “Replicast”. The assignment of responsibilities between the presently-disclosed storage layer and its supporting transport layer is itemized in Table 1 under the description of the scalable transport.

Distributed Object Storage System that Scales Out

The presently-disclosed object storage system provides a method for storing and retrieving chunks encoding object metadata and/or object payload in a distributed object storage system.

Conventional object storage systems rely upon point-to-point connections for all chunk transfers (ingest, replication or retrieval). In contrast, the presently-disclosed object storage system provides effectively reliable access to stored objects built upon unreliable multicast datagrams. By making multicast effectively reliable, it becomes suitable for robust ingest, replication and retrieval of data that is organized into chunks.

Multicast collaboration allows dynamic collaboration in determining which storage servers are storing specific chunks without requiring central or hierarchical control of metadata. Prior object storage systems have chosen between effectively centralized control of location assignment and distributed hash algorithms. However, centralized control of location assignment creates processing bottlenecks that impair scalability of the object storage system, and conventional distributed hash algorithms, while scalable, cannot distribute chunks based on dynamic factors, such as storage server capacity, work queue depths or available network bandwidth.

In contrast, the presently-disclosed object storage system provides distributed control of location selection in a manner that accommodates dynamic loading of servers when making those decisions. This enables the optimization of allocation across storage servers for both storage capacity and dynamic load balancing of the depth of work queues. Hence, the total capacity of the storage cluster, both in terms of TBs (terabytes) of storage and IOPs (input/output operations), can be utilized in an optimized manner even when the cluster has scaled beyond the control of a single metadata server.

Stateless Retrieval

The same Negotiating Group also enables retrieval of chunks without prior knowledge of prior put or replication transactions. Retaining knowledge of prior put or replication transactions in a reliable manner would require centralized metadata. Instead, a get request is multicast to the Negotiating Group specifying a multicast Rendezvous Group that initially only includes the requesting node as the target of the requested chunk (or chunks for certain compound get transactions, to be described). The only server that must track that it has a specific chunk is the server which holds the chunk.

The multicast messages used to respond to a get request may be very similar to those used to put or replicate chunks. They also allow for rapidly pruning the responses from all but the earliest responder to any multicast get request.

The presently-disclosed object storage layer also enables piggy-backing the creation of additional replicas on any get request. Additional targets can be added to the Rendezvous Group and thereby receive the same content that was retrieved for the get requester.

Distributed Editing of the Hash Allocation Table

Multicasting also enables distributed editing of the shared Hash Allocation Table. This enables more flexible tuning of the mapping of Chunk Hash ID to Negotiating Groups than a conventional distributed hashing scheme would allow.

Some of the strategies enabled in preferred embodiments include:

-   -   Having new storage servers wait to assign themselves ranges of         Chunk Hash IDs based upon failure of other storage servers or         detecting an over-loaded storage server.     -   Failing over shared storage devices from one storage server to         another storage server upon failure of the first storage server.

The above techniques enable specific optimization techniques for object-oriented storage systems.

The above techniques may be optimized to provide improved latency when fetching an object stored as a manifest chunk which references multiple payload chunks where the processing of the manifest get issues the first several chunk get requests directly, specifying the Rendezvous Group of the original request. This eliminates the turn-around time required for a client issuing the get for the manifest chunk to issue the get for the referenced payload chunks itself (or from a broker acting on behalf of the client).

Nodes and Network Elements of Object Storage System

The presently-disclosed solution may be implemented using a system comprised of:

-   1) A plurality of nodes that store and retrieve chunks. Some nodes     act strictly as clients, and only accept chunks for the purpose of     delivering them to the end client. A subset of the nodes must be     willing to act as Storage Servers to provide persistent storage for     client nodes. -   2) A plurality of network elements connecting the nodes. The     presently-disclosed solution may rely on existing standard protocols     and use them to provide enhanced reliability without requiring     changes to the network stacks of any of the network elements. The     round trip times within this network may be relatively short and     fairly uniform.

The specific congestion control protocol specified herein requires each node to take responsibility for managing bandwidth reserved for bulk payload delivery to that node.

Methods Provided by the Object Storage System

The presently-disclosed object storage system provides: A) methods for distributing and retrieving chunks using multicast addressing; B) methods for reliable and optimal multicast transmission of chunks by negotiating rendezvous to reserve a Rendezvous Group for a specific transmission during a specific time window; and C) methods for maintaining a shared and distributed Hash Allocation Table without central bottlenecks that could become single points of failure.

A) Methods of Distributing and Retrieving Chunks

The presently-disclosed solution creates a multicast group, named the Negotiating Group, to control both distribution (put) and retrieval (get) of chunks.

Messages may be addressed to either Negotiating Groups and/or to Rendezvous Groups. A Rendezvous Group may be a subset of a Negotiating Group for a put transaction, or a union of the initiating client and a subset of the Negotiating Group for a get transaction. Specifically, the presently-disclosed solution discloses the use of a specialized form of Distributed Hash Table that is a shared and distributed Hash Allocation Table to locate or retrieve the Negotiating Group for a specific chunk in the absence of a central metadata system.

The Hash Allocation Table is used to locate specific chunks in similar fashion to how a Distributed Hash Table would have been used. A Hash ID is used to search for a row in the table, where the Hash ID may have been calculated from the chunk or retrieved from metadata. Where the Hash Allocation Table differs from a Distributed Hash Table is that the method for updating the shared Hash Allocation Table is far more flexible. The method for updating the Hash Allocation Table allows additional servers to be added to the table based on either content already present in the servers or on a volunteer basis. The presently-disclosed solution also allows for servers which are not also clients to hold only the subset of the Hash Allocation Table that is relevant to them.

Each Negotiating Group identifies a subset of the cluster's storage servers that are all of the servers involved in storing or retrieving a specific chunk. Identification of a subset of the storage servers is crucial to allowing unsolicited transmission of buffers without prior bandwidth reservations. If the number of potential unsolicited messages that a given storage server can receive is too large then buffering in the network forwarding elements and the receiving end itself will be insufficient to make delivery of unsolicited messages effectively reliable.

In one embodiment, the Negotiating Group is obtained by a lookup in a shared Hash Allocation Table. This table can be identical in structure to a table that implements a conventional distributed hash table, although the Hash Allocation Table preferably has a variable (rather than fixed) number of members (servers) designated in each row. The Hash Allocation Table differs from a conventional distributed hash table in that there are numerous methods for populating its rows.

As with a Distributed Hash Table, a chunk's Hash Identifier is calculated based upon the chunk's name, or the chunk value (payload). The Hash Identifier is used to look up the row(s) that are used to hold the identities of the servers that are responsible for storing that Hash Identifier. Many methods are well known for performing this type of lookup function.

A negotiation is conducted within the Negotiating Group using unreliable datagrams sent with multicast addressing, as will be specified later, to select a subset of those servers that the chunk must be delivered (or replicated) to.

The presently-disclosed solution requires each chunk to have the following naming attributes:

1) A Chunk ID. The Chunk ID uniquely identifies the chunk and which will never reference a different payload. It must be effectively globally unique for at least twice the lifetime that the chunk will be retained or referenced.

2) A Content Hash ID. Each embodiment of the present invention selects a specific hash algorithm that all servers in the cluster agree upon. If the selected hash algorithm is a cryptographic hash of the content, such as SHA-2 or SHA-3, then the Content Hash ID may also serve as the Chunk ID. When the Content Hash ID also acts as the Chunk ID, the algorithm selected is preferably strongly resistant to pre-image attacks. When only used to validate content, the hash algorithm merely has to be resistant to coincidental collisions. Whether or not it is used to identify the chunk, the Content Hash ID is always used to validate the content of transmitted chunks or chunks retrieved from persistent storage.

The Chunk ID should have a uniform distribution so that it can be used to efficiently index locally retained chunks on storage servers. In a preferred embodiment, the Chunk ID is always the Content Hash ID. Cryptographic hash algorithms generally provide a uniform distribution. In alternate embodiments, the Chunk ID may be supplied as an Arbitrary Chunk ID by a centrally controlled metadata system (such as an HDFS namenode). That metadata system would be responsible for creating Chunk IDs that with a uniform distribution.

A chunk may also have a Name Hash ID. Chunks that are used to store the root of metadata for a version of an object within the storage system also have a name that can be used to retrieve the chunk object. The Name Hash ID is an additional partial identifier for such chunks (the addition of a version identifier is required to form a complete additional identifier). In a preferred implementation where these indexes are implemented is a single flat index, entries found using the Name Hash ID will contain the Chunk ID while those found with Chunk ID will specify the local storage locations where the chunk payload is stored and the chunk back-references are tracked.

When working with chunks that have a Name Hash ID it is used to index the Hash Allocation Table to retrieve the Negotiating Group.

A1) Distributed Put Operation

The above-described FIGS. 6-15 provide illustrative examples of transactions to put a chunk to an object storage system in accordance with the presently-disclosed solution.

The first step in a distributed put operation is for the data source to identify the Negotiating Group comprised of the set of target storage servers that should receive a Chunk Put proposal for the chunk.

A1a) Identification of the Negotiating Group

The Negotiating Group may be identified through several methods, including the following:

-   -   1. By looking up the Name Hash ID for the chunk in the shared         Hash Allocation Table, or looking up the Content Hash ID in the         same table when the chunk does not have a name. An unnamed chunk         may be identified directly or indirectly from the contents of a         named Chunk. The Negotiating Group row so found would list the         target servers for a range of Hash IDs, and a Multicast Group ID         already associated with this group.     -   2. In alternative implementation, the Negotiating Group may be         identified by a central metadata system, such as a namenode in         the Hadoop Distributed File System (HDFS).

A1b) Chunk Put Proposal

Having selected the set of targets, a Chunk Put Proposal is sent to this Negotiating Group (Designated Super-Group). A Multicast Chunk Put Proposal message may encode at least the following information:

1) An Identifier of the target Negotiating Group.

2) An enumerator specifying the Type of a Chunk Put. These types would include Payload Chunk, Version Manifest and Chunk Manifest.

3) The Content Hash ID for the chunk.

4) If this is a named chunk (which holds the root of the metadata for a version of an object), then the name of the object to be put must be specified. In a preferred embodiment, this includes the Name Hash Id of the enclosing Container (commonly referred to as a “bucket”), the Name Hash ID and the unique version identifier for the version to be created.

5) The total length of the content that will be put.

6) The total length of the above content that will be put immediately using unsolicited bandwidth, typically in an optional portion in this message.

7) The multicast address for a Rendezvous Group that will be used to put the payload. The members of the Rendezvous Group are not specified because they have not been selected yet.

8) Other information as required by the transport layer.

A1c) Chunk Put Accept

A Chunk Put Accept message encodes the following information:

1) The identity of the Put Proposal that this is in response to: Requester, Sequence # and sub-sequence #.

2) One of the following three responses:

a) Chunk already stored. Redundant transmission of the chunk payload is not required.

b) Put Proposal Not Accepted (“Not Now”). The additional payload will indicate the earliest time when this Storage Server would want to consider a retry request.

c) Put Proposal Accepted. The additional payload will indicate the time window and data rate reserved for this delivery.

Dependent on application layer logic, the Data Source will have a policy on the desired number of targets it wants to deliver the chunk to on a first round. In some cases there will already be enough targets holding the chunk that no further deliveries are needed. Otherwise, the Data Source will determine the Rendezvous Group for the payload, which is a subset of the Negotiating Group.

Consider an example with four Data Sinks in a Negotiating Group. In this example, three of the Data Sinks may accept the put proposal, while the fourth may indicate that it cannot accept the chunks being put currently (by sending a “Not Now”). Typically, the acceptance criteria for an “adequate” number of Accepts may be that at least one of the acceptances is from one of the “designated” servers, and there must be a total of “replication count” servers in the rendezvous group.

A1d) Rendezvous Transfer

The Chunk Source will then initiate a Multicast Rendezvous Transfer to the Rendezvous Group at the consensus time. The mechanisms for implementing a multicast rendezvous transfer are dependent on the transport layer.

A1e) Payload ACK

Each recipient of a Rendezvous transfer that is part of a get transaction will either acknowledge successful receipt of the entire chunk (or negatively acknowledge failed reception) with a Payload ACK. A Payload ACK is also generated in response to a Put Proposal that included the entire payload.

Processing of a received chunk by the upper layer must be complete before the Payload Ack is transmitted. The received chunk must be persistently stored, or applied and the results appropriately stored, before a Payload Ack is sent. When a storage server is responsible for providing persistent storage, the results must be persistently stored before a Payload Ack is appropriate.

The Payload ACK must be sent both to the Data Source and to a multicast group of all servers that wish to track the existence of chunks mapped by a row of the Hash Allocation Table. Such a group may be a specific member of the Multicast Address Set or may be the default multicast address for the Negotiating Group.

An alternative method is to have each recipient of the Chunk Put message send just a unicast Payload ACK to the Data Source. The Data Source then prepares Relayed ACK messages summarizing one or more received Payload Acks; these messages are sent to the appropriate multicast group.

The destination group may be the Negotiating Group itself, or may be a companion multicast address taken from the Multicast Address Set for the Hash Allocation Table row where that member is designated for Payload ACK messages either in general or specifically for named chunks.

In a preferred embodiment, the Payload ACK encodes the following information:

1) The identity of the Put Proposal that is being completed.

2) The Chunk ID that is being acknowledged.

3) The status: successful or not. Indicating specific reasons for a negative acknowledgement is useful for diagnostic purposes, but is not necessary for the functionality of the present invention.

4) When successful, the message includes an identifier of the server that now has this chunk stored.

When the Payload ACK was only unicast to the Data Source, the Data Source must multicast a Relayed ACK to the Negotiating Group to inform the members of the group of which servers now have this chunk stored. The Data Source may aggregate multiple Payload ACKs for the same chunk into a single Relayed ACK message.

A1f) Making the Put Transaction Reliable

Finally, the Chunk Source evaluates whether there has been a sufficient set of positively acknowledged deliveries of the chunk. Such a determination may be more complex than merely checking the number of delivered chunk. For example, an embodiment may require that a minimum number of the servers that are permanent members of the Negotiating Group hold the Chunk. A storage server that offered only volatile storage might be acceptable as an additional copy, but not one that can be relied upon. However sufficiency of delivery is evaluated, if insufficient replicas have been created, then the Chunk Source and each successful recipient of the chunk will attempt to put the chunk again after a random back-off delay.

In one embodiment of this collaboration, each interaction described is encoded as a PDU (Protocol Data Unit) which becomes one or more L2 frames. Each PDU is delivered to the set of storage nodes identified by a Multicast Address, whether by a natural Multicast protocol such as multicast UDP over IP or by cut-through replication using unicast connections such as TCP over IP.

The decision to use a native multicast protocol or a unicast simulation thereof can be made independently for the control PDUs (Get Request, Chunk Put Proposal, Chunk Put Accept and Payload ACK) and the payload delivery PDUs.

In one embodiment, multicast is used for payload delivery and IGMP is used to control membership in the multicast group. In these embodiments each Data Sink joins the multicast group before the time window accepted in their Put Accept reply, unless they specifically indicate that they anticipate the offer will be rejected.

A2) Cluster-Wide Timestamp

The presently-disclosed solution assumes a common timestamp maintained by all members of the storage cluster. There are several well-known techniques for maintaining an adequately synchronized clock over a set of distributed servers, and any of which are suitable for an implementation of the present invention (e.g., Network Time Protocol and/or Precision Time Protocol).

A3) Distributed Get Operation

The above-described FIGS. 16-21 provide illustrative examples of transactions to get a stored chunk in accordance with the presently-disclosed solution. In the example shown in FIGS. 20-21, the chunk is also replicated to a volunteer Storage Server to provide additional replicas. The presently-disclosed solution allows for opportunistic replication of the chunks most frequently retrieved, thereby optimizing later retrieval of those same chunks.

The first step of the distributed get operation is for the client, or an agent acting on behalf of the client, to join a Multicast Rendezvous Group previously provisioned for use by this client. Typically, the client will have joined several provisioned Rendezvous Groups for previous transactions and will be selecting one of the groups previously used for a completed transaction.

A3a) Multicast Get Request

The client then issues a Multicast Get Request to Negotiating Group appropriate for the requested chunk. The group is identified just as described for the put procedure.

This Multicast Get Request includes, but is not limited to, the following:

1) Identification of the transaction:

a) A Source ID of the client or its agent.

b) A transaction sequence number.

2) Identification of the chunk desired. Depending on the application layer this may take multiple forms. This could be any of the following:

a) The exact Chunk ID of any chunk that does not have a Name Hash ID. This Chunk ID will typically have been obtained from a metadata chunk that did have a Name Hash ID.

b) The exact Name Hash ID of an Object combined with an optional specification of a desired version.

3) The Rendezvous Group for this Get Request.

4) The maximum amount of unsolicited content that may be delivered in each response.

5) A Reception Window when the client will be ready to receive the response. This is the same information as provided in the Put Accept message.

6) A maximum number of auxiliary responses that may be generated for this request. Once a storage server is acknowledged as the responder for this request, it may issue Get requests for up to this many chunks referenced by the main requested chunk. For each of these allowed auxiliary responses a separate reception window must be specified.

7) Optional additional reception windows that can be used for auiliary responses.

In the typical case, there will be no Additional Target Requests generated. We will therefore complete this description without any having been generated, and discuss additional targets after completing an initial description of the get algorithm.

For a Get Request which specifies delivery immediately or relatively promptly (as defined by system-wide configuration), each Storage Server in the Negotiating Group possessing the chunk requested will attempt to respond to the get request as soon as its internal work queues allows it to. However, only the first responding Storage Server will actually completely respond and deliver the requested chunk. The mechanisms to ensure that only one response is generated for each Get Request are dependent on the protocol used to implement this collaboration.

Note that an embodiment may also define a Unicast Get Request. This would be a Get Request sent to a specific storage server. Such a capability would largely be used for diagnostic purposes, as that there would be no end-user advantage to requesting a chunk be delivered by a specific storage server.

A3b) Multicast Get Response

Each designated storage server will attempt to respond with a Multicast Get Response message. These responses will be collected either by the client or by the Negotiating Group, resulting in a single source being selected. The Multicast Get Response includes, but is not limited to, the following information:

1) The Timestamp of the response.

2) The Source ID and IP address of the responding server.

3) Identification of the Multicast Get Response that is being responded to, and which portion of the response this is: The primary content or the ordinal offset of which referenced chunk is being transferred.

4) The Rendezvous Group ID that will be used (which is repeated from the Get request).

5) The rate at which the chunk will be transmitted.

6) The Content Hash ID of the chunk it will deliver, and if this is a named Chunk the Name Hash ID and unique version identifier of the chunk.

7) If the requested chunk is too large, an error will indicate this problem and specify the actual metadata and payload lengths. Otherwise any immediate portion of the requested content. The entire contents requested consists of:

a) The Metadata Length, and the metadata and integrity checking data

b) The Payload length, length and the payload.

In some embodiments, a storage server may respond with a Content Not Immediately Available message that indicates that it cannot return the content requested until at least a specified time. This would typically be due to having previously migrated the requested chunk to offline storage. Issuing such a response indicates that the process of moving the requested chunk back to online status has been initiated. However, the request should be re-issued at some time after the time indicated.

Each respondent only sends the first datagram in the response. This response is sent using unsolicited bandwidth. The balance will only be transferred once this specific server has been selected to perform the rendezvous transfer using reserved bandwidth.

Unless the entire response fits in a single datagram, a single responder must be selected to complete the transfer. This may be the Chunk Sink or the primary member of the Negotiating Group offering to deliver the content. This selection is multicast as a Multicast Get Accept message to the Negotiating Group, and the selected server will then begin the transfer.

The selected rendezvous transfer is then initiated using reserved bandwidth by the selected storage server to the Rendezvous Group specified in the original Multicast Get Request.

A3c) Emergency Get Request

Before failing a request to get a chunk that is believed to exist because there are no responses from the Negotiating Group, a requester will resend the Get Request to all storage nodes rather than just to the Negotiating Group.

A storage node knows that a chunk should exist when it is referenced in another chunk, or when a request is made for an object by a client that does not have a history of requesting non-existent chunks. In order to prevent a denial of service attack, repeated requests from clients for chunks that do not exist should not result in issuance of Emergency Get Requests.

A4) Volunteer Servers

Some embodiments may deploy volunteer servers to enhance the overall responsiveness of the storage cluster. Multicast communications allow them to be effective general purpose caching machines without forcing requests to go through them (at the cost of slowing down all responses where there is no cache hit).

A4a) Accepting Content during an Initial Push

When a Volunteer Server receives a Put Proposal for content it does not have, it may determine that it should volunteer to accept the new content.

The Chunk Source will understand that the response from the volunteer server does not represent a reliably persistent storage server for the content. Any determination that a transaction has been successful will require a minimal number of designated, or permanent, members of the Negotiating Group.

The probability of a volunteer target server issuing a Put Accept for a chunk should be dynamically adjusted as follows:

-   1) Having larger local storage capacity that is not currently used     should increase the probability of issuing an Additional Target     Request. -   2) Having backlogged queues of already committed work that is not     yet completed should radically decrease the probability of issuing a     Put Accept. -   3) The existence of Put Accepts from other Volunteer Servers for the     same chunk should decrease the probability of issuing further Put     Accepts.

A4b) Accepting Content piggy-backed on Content Delivery

When a Volunteer Server receives a Get Request for content it does not have, it may determine that it should volunteer to hold a replica of this data.

The Volunteer Server issues an Additional Target Request to the same group that the Get Request used. The Additional Target Request requests that the Volunteer Server be included in the delivery as well. When an IGMP controlled multicast protocol is used the volunteer server may simply join the Rendezvous Group specified in the Get Request. The additional target merely has to attempt collection of the chunk on that multicast group, and saving it if it is received successfully. With a non-IGMP controlled multicast protocol, the responding server will have to add the server to the Rendezvous Group. Again, the target merely has to attempt collection of the chunk on that multicast group, and save the chunk locally if successful. With a unicast chain put payload, the first responding storage server must add the server to the list, which will result in the same chained delivery as described for the put algorithm, except that no Payload ACK message is required.

The probability of a volunteer target server issuing an Additional Target Request should be dynamically adjusted as follows:

1) Having larger local storage capacity that is not currently used should increase the probability of issuing an Additional Target Request.

2) Having backlogged queues of already committed work that is not yet completed should radically decrease the probability of issuing an Additional Target Request. The longer the delay before a delivery is initiated (due to source/network congestion, not for delays due to delayed delivery of subsequent chunks for streaming, due to delays should increase the probability of issuing an Additional Target Request. A chunk which cannot be retrieved promptly will more frequently be in need of additional replicas chunks which can be retrieved promptly. A request that a client had to retry is an extreme example of a long delay, which should result in a marked increase in the probability of issuing an Additional Target Request, perhaps even to the extent that two additional targets may be selected.

3) The existence of Additional Target Requests for the same chunk from other servers should decrease the probability of issuing further Additional Target Requests. Adding one extra server per chunk get is often sufficient (this will be the subject of testing and tuning efforts).

In a preferred embodiment, Additional Target Servers should place the additional local copies of chunks on a “short fuse” queue for deletion of these chunks with an adaptable heuristic based on Most Frequently Used and Most Recently Used tagging of chunks. The chunks at the end of this deletion queue should be deleted from the Additional Target Server to make room for Additional Target Requests based on the total number of Additional Target Requests that a Volunteer Server can support.

A4c) Responding to a Get Request for Content Held

Unlike a designated, or primary, member of a Negotiating Group, a Volunteer Server is not obligated to respond to a Get Request even if the Chunk is stored.

Of course, there is little point in volunteering to be an extra replica, unless the server will generally respond to Get Requests, but there are several reasons why it might not be advantageous to respond to a specific request:

-   1) The work queue might already have several requests. -   2) There may be a queue to even validate whether the chunk is     locally stored. -   3) There are already responses from other storage servers that are     sufficiently equivalent (even if technically later than this server     could respond) that there is insufficient benefit in responding.

A5) Non-Immediate Requests

In accordance with an embodiment of the invention, a Get Request may specify non-immediate delivery. Here are some examples of when non-immediate requests may be employed:

-   1) Retrieving archive objects from an archive with slow media (e.g.     tape); -   2) Copying an object from a server with slow media to a server with     fast media in anticipation of forecasted demand for the objects     (e.g., email boxes between 5-6 AM before start of business at 8-9     AM); -   3) Copying objects to an archive server as a replication for backup;     and -   4) Replication of chunks can be performed on a “lazy” background     basis once the minimum set of copies are guaranteed.

Non-immediate requests may be useful for applications such as retrieving archived objects when no user is waiting for the specific content, or other cases where the consumer wishes to use low priority (and presumably low cost) delivery resources but still eventually receive the requested chunk.

In a preferred implementation for such requests, it is best to pick the member of the Designated Group that effectively has the lowest bid for providing the requested chunk. Rather than selecting the storage server to perform the actual delivery based on the first responder, the members of the Designated Group would multicast a “delivery bid” message to the other members of the group, identifying the Get Request and a nominal price for the delivery. The lowest bidder would submit their “winning” bid to the client, and then deliver the requested chunk at that later time.

Each storage server can apply its own heuristics to determine the nominal price to assign to its response. However, having other deliveries of different chunks at nearly the same time would typically increase the nominal price. Factors that could lead a storage server to offer a lower price include probable caching of the requested cache because of other scheduled deliveries of the same chunk, and whether the drive storing the requested chunk would be already powered up at the requested delivery time.

Similarly, a Chunk Put Proposal can be for a non-immediate push. The recipients of a non-immediate Chunk Put Proposal would respond with either an indication that the chunk was already stored on this storage server or a Put Deferred Accept message that would identify one or more broad time windows when it could accept the chunk, and a nominal price for the delivery. The client would accept a window that had the lowest aggregate cost (based on the nominal prices quoted in each response) and send a Put Deferred Accept message indicating the exact time window when delivery will occur. The selected servers would then make the required bandwidth reservations. With any non-immediate delivery the target may have to cancel the reservation, in which case it should notify the source so that it can seek other targets either at the same time or at a later time.

A6) Target Response

In the Chunk Put Accept response, each target indicates when it expects it will be able to receive the bulk content of the object being put. This must be based upon both the target's internal queues for writes to persistent storage, the amount of room that will be available in ingestion queues and the probable availability of network bandwidth.

Under the presently-disclosed solution, each implementation is responsible for selected a congestion control protocol which will prevent virtually all failed message deliveries due to dropped frames caused by network congestion.

A7) Opportunistic Storage Servers

When joining an existing storage cluster, an implementation may configure new storage servers to refrain from claiming the portions of the Hash ID ranges that a default hash algorithm would have assigned to it.

Instead, the new storage servers will retain its capacity and seek to assign itself ranges of Hash IDs when it detects the following conditions:

-   1) When a storage server departs the ring, relatively under-assigned     storage servers will seek to claim the Hash ID range previously     handled by the now departed storage server. -   2) When get requests for a given hash id range are taking longer     than average a relatively under-assigned storage server will seek to     make itself one of the designated servers for a portion of that     Chunk Hash ID range.

B) Methods of Reliable Multicast Payload Delivery

Although multicast is typically perceived as an unreliable protocol, on most wired LANs, the number of congestion drops or misdelivered packets is extremely small. Since multicasts still have a non-zero probability of not reaching all of the target servers, Replicast has mechanisms that add reliability to an inherently unreliable protocol, but without the overhead of “reliable” transport mechanisms like TCP/IP.

B1) Source Server Responsibilities

The essence of the “reliability” of the Multicast Payload Delivery is that it does not depend on the original “source server” to insure that all of the copies are made. The “source server” is only responsible for the minimum set of copies. Once those copies are guaranteed, then the application returns control to the user application that created the object. Replication of chunks in the presently-disclosed solution is an ongoing process that does not end.

B2) Distributed, Reliable Chunk Replication

Now a distributed mechanism comes into play. Each of the Chunk copies (note that the original “source server” may be one of these chunk copies that is not a designated copy) keeps a list of the designated destinations for the chunks (the size of this list is controlled by the replication count for the object, which can also vary by object). If any of the destinations does not yet have a copy of the chunk, then the server holding the chunk wants to “mate” with one or more of the destinations so as to reproduce the chunk. The distributed replication is an ongoing responsibility of each chunk server. The replication retries are a continuous background task for the storage servers. However, to avoid network congestion, each of the retries may be done on a random interval basis, analogous to the CSMA/CD collision detection and retry mechanism. In this way, the replication task is spread across many different servers and not left to a single source server.

This task to replicate may exist for each storage server regardless of its retention of a list of known other replicas. Retaining such data enables optimization of the replication process, but is not necessary for its correctness.

This same mechanism for performing replication may be used whenever servers join or leave the ring of servers. Each chunk server is continuously updating the list of servers that have copies of a chunk (including manifests). If due to ring membership, caused by a failed server or a partitioned network, there are insufficient replicas of a chunk on designated servers, then it is the responsibility of all chunk owners to attempt to replicate to the designated servers (as noted in the chunk manifest and hash row). Because this data can be volatile, a “get” type of query may be issued to reconstruct the list of chunk copies.

In preferred implementations, the multicast addressing can be utilized for payload delivery as well as for “unsolicited commands” that carry a payload, rather than negotiating for a time to send the payload. Preferred implementations will insure that the network switch has been provisioned so that the bandwidth allocated for storage and “unsolicited” traffic is non-blocking up to a pre-determined limit and that the network will not experience congestion as long as the process of reserving payload transmission does not exceed that threshold. This helps to ensure that the “unreliable” multicast is actually quite reliable since it does not run the risk of data loss due to network congestion.

While all commands and payload transfers may be retried, they can avoid the need to retransmit by

-   -   1. Protecting the storage traffic from general purpose traffic         not complying with these special rules;     -   2. Limiting the bandwidth for unsolicited transmissions to a         provisioned rate;     -   3. Limiting the bandwidth for reserved transmissions to a         provisioned rate; and     -   4. Only utilizing the reserved bandwidth in accordance with         rendezvous agreements negotiated using unsolicited         transmissions.

C) Methods for Generating and Editing the Hash Allocation Table

The classic methods of generating a hash allocation table will typically result in a fairly uniform distribution of chunks over the servers. However, it is an inflexible distribution. Existing designated hash tables may cause the cluster as a whole to be declared “full” when a single storage server is full. The fact that there is storage available on other servers is irrelevant; there is no space on the storage servers specified by the distributed hash algorithm. If the chunks cannot be stored where readers will look for them, then they cannot be stored.

The improved editing of the Hash Allocation Table replaces a fixed distribution based strictly on a hash algorithm with flexible table driven distribution. The table is no longer maintained by multicast distribution of joins/departures but rather by multicast distribution of edits.

The presently-disclosed solution relies on sharing a mapping of hash IDs to multicast addresses and/or lists of storage servers. This is referred to as a “Hash Allocation Table”. In one embodiment, the Hash Allocation Table is implemented as a memory array on each storage server with specific methods used to guarantee that the same table is generated on each storage server. As those skilled in the art will recognize, a “table” may be thought of as a mapping that can be implemented in numerous ways. It is defined by the data which that a key value retrieves, rather than by the specific method used to encode and store the rows of the table.

The presently-disclosed solution requires a Hash Allocation Table that is updated whenever the set of storage servers changes, or when redistribution of the workload is required. There are many methods by which this can be achieved:

-   1) A designated server could collect changes in the membership of     the storage cluster, generate a new hash allocation table, and then     distribute it to all servers that needed it. This technique is     compatible with the presently-disclosed solution. -   2) Having each server generate the table based on the cluster     membership reported by a distributed keep-alive ring is also     compatible with the present invention. -   3) A new method is described herein where the storage servers may     multicast edits to the entire storage cluster in a fashion where all     edits to the table will be applied, but in a consistent order by all     members of the cluster.

In accordance with an embodiment of the present invention, the Hash Allocation Table may be edited on two different planes:

-   -   4. One plane deals with the assignment of Multicast Address Sets         to specific rows of the Hash Allocation Table. This plane also         tracks Multicast Addresses which have been provisioned for the         system but which have not been assigned to a Hash Allocation         Table row.     -   5. A second plane deals with the addition and deletion of         storage servers to specific rows of the Hash Allocation Table.

A versioned object created within a reserved namespace of the object storage system is used to assign Multicast Address Sets to rows of the Hash Allocation Table and to track spare Multicast Addresses not yet assigned to a row. All servers with access to the Replicast traffic would subscribe to this object so as to always fetch the most recent version of this object (or alternatively to have that version pushed to them).

The edits to the membership of the Hash Allocation Tables edit the membership status of a specific storage server for a specific row. A membership type can be full, limited or non-existent (i.e., delete this entry).

There are at least two valid strategies for reliably editing the memberships in the Hash Allocation Table:

-   -   There are well-known prior art techniques for the members of a         ring identified by a Keep-alive subsystem to serialize all edits         to a common table. After serialization, each member of the ring         applies the edits in order, resulting in all servers being in         agreement on what the resulting table should contain.     -   Multicasting the edits may be made reliable by having the         multicast edits be acknowledged through the keep-alive         functionality itself. After each edit, each storage server         computes the signature of the resulting table and the timestamp         of the most recent edit applied. This information may be shared         through the keep-alive heartbeat messages amongst the members of         the cluster.         -   If there is a later edit that a specific storage server had             not been aware of, it can send a multicast request that the             specific edit be retransmitted. This should result in that             server receiving the edit it had missed, applying it, and             then joining the consensus as to what the signature of the             Hash Allocation Table should be.         -   If this fails to result in consensus, ultimately the             majority of the ring will declare the minority to be wrong.             This will result in those storage servers leaving the ring,             and then rejoining it, and then having their Hash Allocation             Table be rebuilt based upon the consensus of the majority.

This technique relies upon an implicit acknowledgement of a table edit in the keep-alive synchronization of the Hash Allocation Table signature through the keep-alive subsystem. Inherently, the Hash Allocation Tables cannot be guaranteed to always be identical for all storage servers; the best that can be guaranteed is that the storage servers will converge upon having the same Hash Allocation Tables. However, the presently-disclosed solution relies upon synchronization of the Hash Allocation Table only for efficiency. Even if the complete Hash Allocation Table were lost, all storage servers would seek to repair the table claiming ranges stored locally. Once a new table was agreed upon, all servers would seek to ensure that content stored locally was adequately retained on the designated servers, and multicast put proposals to achieve that goal. Brief discrepancies of isolated rows in the table do not imperil the overall integrity of the distributed storage system.

Server-Specific Heuristic Algorithms

The presently-disclosed solution describes a number of steps that must be implemented by specific storage servers. For example, each storage server estimates when it will be ready to accept a chunk for permanent storage. It is important to understand that the presently-disclosed solution does not restrict the algorithms that any embodiment of any storage server may use to make that estimation.

There are many methods for estimating when the work in a queue will be completed. Many of these methods are well known. Any of these methods are compatible with the presently-disclosed solution. The critical requirement is that each storage server is able to derive its own estimate with the information provided independently without relying on any other storage server.

The presently-disclosed solution may be considered to be an enhanced version of a “share nothing architecture” in that each storage server is independent, and self-sufficient. Further, there are no single points of contention or bottlenecks in the system. However, the presently-disclosed solution widely shares information through multicast within the cluster. For example, all members of the Negotiating Group will typically be notified of each Payload Ack for a chunk in that group. This information can be used by each server's local heuristics to optimize algorithms such as determining when a chunk should be replicated.

The presently-disclosed solution remains a “share nothing architecture” because there is no reliance upon this shared information. It is ephemeral shared status being reported through the cluster. The shared information may be used to enhance behavior, but the loss of this information creates no failures. Some heuristic algorithms may find less optimal solutions, but never an incorrect solution.

Voiding a Designated Chunk Server

A chunk server that has some functional impairment must perform two steps without necessarily shutting down the server. First, it must leave the ring of chunk servers as a designated destination for ingesting new chunks/objects. The byproduct of this step, as with any server that departs the ring of chunk servers, is that all chunks, for which this is the designated server, must void that server as an available designated copy. This in turn will trigger the step to visit each of the (now read-only) chunks that are held on this server and begin the processes.

Variations in Participation by Negotiating Group Members

The Negotiating Group for a specific range of Chunk Hash IDs (i.e., a row of the Hash Allocation Table) identifies the set of storage servers that should receive get or put requests for those chunks. However, not all members of this group are equal. Consider, for example, chunk servers with volatile storage and source-only chunk servers.

1) Chunk Servers with Volatile Storage:

For example, a member may indicate that it should not be counted toward the minimum replication count. Such a server may store chunks in this range, and deliver them when requested. However, it might not guarantee persistent storage. A storage server that uses only very high-speed volatile storage (such as DRAM) is one example.

2) Source Only Chunk Servers

A storage server may also be in an impaired but still functioning state. Such a server no longer has functionality in some of the resources it relies upon to provide persistent storage that is available on demand.

Some examples of impaired servers include:

-   -   The server may have lost one (or more) drives of a mirrored set.     -   The server may have lost one of several network interfaces.

While still functional, the chunks held by this storage server are now a single hardware failure away from being unavailable. This will normally trigger voiding the “designated” status of chunks held on this server. This should trigger process to elect a new designated storage server that is not in a failure state, and replicate the chunks on this server to other servers. Impaired servers should not accept new chunks to be stored, but are still valid sources for triggered replication and for responding to get requests.

Transaction Authentication Token

Some embodiments of the presently-disclosed solution may require the Chunk Source to obtain a Transaction Authentication Token before starting a transaction to put the Chunks for a given object. When required, this token is obtained by supplying user credentials and the identity of the object to be created or edited to the storage servers in the Negotiating Group where the named chunk for the object will be put to complete the transaction.

The token will encode this information and include a signature proving that it was signed by a storage server authorized to validate object access in the object storage system. The signing storage server will have first validated that all required access control rules for the specific object storage system have been met.

When required by the specific implementation, this token must be supplied with each Chunk Put proposal for authentication. It may be stored as metadata to facilitate chunk cross-referencing and to enable auditing of chunk storage.

A specific embodiment may also provide a Transaction Authentication Token with the results for getting a Chunk that is the root of the metadata for an object.

This Transaction Authentication Token would then be provided with each Get Request for the other chunks of that object.

Periodic Chunk Replication

Chunks are also periodically replicated to new storage servers. The presently-disclosed solution does not require any prioritization of replication. If all storage servers seek to replicate all chunks they have stored the storage cluster will quickly converge on having enough replicas of all chunks. Implementations may have specific strategies for prioritizing chunk replication so as to attempt replication on those most likely to need additional replicas. Reasons for optimizing specific chunks include changes in the Hash Allocation Table or for changes in implementation specific storage policies.

The procedure to replicate a chunk is basically the same as for putting a chunk. However, rather than supplying a Transaction Authentication Token a full enumeration of existing back-references for the chunk is supplied as metadata in addition to the payload.

When replicating a range of Hash IDs a storage server will replicate named chunks using the Name Hash ID index and use the Chunk ID index to access general chunks, but exclude those chunks that are used solely as Named chunks.

Compound Get Request

In one embodiment of the present invention, the process of getting an object is further optimized for distributed object storage systems which store metadata for a version of an object separately from the payload. The version manifest, or metadata, contains references to the chunks/blocks.

In a default implementation, the issuer of a Get Request may obtain the version manifest chunk, and then issue Get Requests for the referenced payload chunks. This pattern is used in both pNFS (parallel NFS) and the Hadoop Distributed File System (HDFS).

In an optimized implementation, the storage server holding the version manifest chunk may originate Get Requests for a specific number of the initial payload chunks referenced by the version manifest. These requests specify the originator of the Get Request as the target.

When a multicast protocol is used to deliver the payload each Chunk Put PDU specifies which chunk of the overall object it is. This information may be supplied in the Get Request from the storage server holding the version manifest.

When a unicast protocol is used, the Get Request includes a port number to be used for each of n chunks. This port number is provided in the relayed Get Request, which will identify which chunk is being delivered to the end recipient.

Stability Across Power Reset

One desirable characteristic of a chunk distribution algorithm is that the same set of storage servers will reliably recreate the same distribution after a full system wide reset. The presently-disclosed solution retains compatibility with this feature by having each storage server retain in persistent storage those rows in the persistent hash table that reference them, and the total number of storage servers in the keep-alive ring.

The keep-alive system is also required to track how long each server has been a member of the ring. Upon restarting, each storage node will determine whether it should reapply its previous row assignments. It will not do so when heuristic rules suggest that it has rejoined a static ring. Indications of this would include a large portion of the members having been running for a configurable time period, and the population of the ring being on par or greater than the previous population.

Tracking Ongoing Reception

Each node in the system notes all chunk retrieval requests it receives. Even if it does not join the Rendezvous Group, it will still receive either a multicast Payload ACK or a Relayed ACK indicating final delivery status for each chunk to each member of the Rendezvous Group. While a chunk is being delivered, there is no need to start a new delivery for the same chunk.

Extending Existing Central Metadata Systems

In an alternate embodiment, a central metadata system may be extended so that the central metadata server specifies the location(s) of a chunk as the Negotiating Group. The specific set of storage servers is negotiated within the Negotiating Group. Chunks are retrieved by asking the central metadata system where they are located, and then multicasting a request to the Negotiating Group specified for the requested chunk.

These techniques offload the central metadata server from tracking the dynamic state of each chunk/block storage server it controlled. However, these techniques would still rely on a central metadata control system and would therefore still be constrained (throttled) in the same way that any centralized system would be constrained.

Summary of Features and Advantages of Disclosed Object System

The presently-disclosed object system allows the set of storage servers providing persistent storage for a chunk to be selected from those that can store the chunk most promptly, rather than arbitrarily selecting a set of storage servers without regard for network traffic or server workloads.

In prior art, selecting storage servers based upon their current loads was limited to systems with a centralized metadata system, such as HDFS and pNFS.

The presently-disclosed object system allows the Chunk Source to select the optimum set of storage servers to take initial delivery of a chunk from amongst the Chunk Put Accept responses collected to a multicast put proposal. Centralized metadata solutions can only perform this optimization to the extent that the central metadata server is aware of the resource status of every storage server in the cluster. Existing Distributed Hash algorithms can only adjust boundaries for longer term changes in the distribution. Any change in the distribution of chunks requires moving previously committed chunks. Only major changes in the distribution can justify the migration costs of adjusting the distribution.

The presently-disclosed object system allows the initial source of a chunk to select the initial Rendezvous Group. In selecting the initial Rendezvous Group, the source server has many options to influence the members of the group. Some of the considerations include, spreading replicas across failure domains, selecting destinations that have the largest amount of free space, destinations that have a best rating (combination of CPU power and memory space available) as well as other factors that can vary dynamically, including the speed, number and/or cost of the link(s) between the source and the sink.

The presently-disclosed object system allows storage servers with excess capacity and currently low work queues to volunteer to provide additional replicas of chunks. In fact, many storage systems have the notion of “hot stand-by” drives that remain powered up, but idle, to step in when an existing drive fails. With the presently-disclosed object system, these hot stand-by drives can be used to perform a performance enhancing “volunteer” duty to hold volatile extra copies of objects. Clients can find these additional replicas using the Negotiating Group. The Negotiating Group also enables collaboration within the group can be found by clients seeking those chunks and/or when replication of those chunks is required due to the loss of an existing storage server (or the additional of a new storage server).

The presently-disclosed object system also allows for dynamically adjusting the Hash Allocation Table to dynamically load-balance assignment of responsibilities among the storage servers. The presently-disclosed object system enables alternate strategies, such as holding new servers in reserve to replace failed or to offload overloaded servers. Prior art could only provide this type of flexible resource assignment by centralizing the function of the metadata server.

The presently-disclosed object system also improves utilization of network bandwidth and buffering capacities.

Network elements may quote bandwidth capacities as though they were reserved. However, this is not how network elements actually operate. Buffers are not pre-enumerated for different classes of service; they come from a common pool. Stating that the network element has a queue for up to 40 Ethernet frames in Class X does not mean that there are 40 buffers pre-allocated for that purpose. Rather, it means that after 40 frames are queued for Class X, further frames for Class X may or will be dropped, and that no frames for a different Class that is below its quota will be dropped because an excessive number of frames for Class X were queued.

This can be thought of as a reservoir with controlled ingress and egress rates. In aggregate, it is known that 30% of the water in the reservoir came from river W, but that does not mean that it is easy to find the specific drops in the reservoir.

With tailored multicast as disclosed herein, the time that copies of a given chunk will be in network element buffers is greatly reduced. With unicast protocols, a buffer will be required for the reception time, queued time and transmit time for each of the three copies. With the presently-disclosed solution, a single buffer will only be held for the reception time, the longest queue time of the three copies and transmission time. While this will be more than one third of the time buffers will be held for the unicast protocols, it is still a considerable improvement.

Even if there are no changes in the class of service traffic shaping for any of the Ethernet priorities, this now unused buffer capacity can enable more unsolicited messages and more non-storage packets to be successfully delivered over the same local area network than could have been delivered had a unicast delivery strategy been used. Less buffering also means prompt transmission, which will improve average delivery times.

In summary, the presently-disclosed object system provides the following:

-   -   A method for distributing and retrieving chunks using multicast         addressing to Negotiating Groups and Rendezvous Groups that are         subsets of the Negotiating Groups.     -   A method for using a specialized form of Distributed Hash Table         that is a shared Hash Allocation Table to find the Negotiating         Group for a specific chunk in the absence of a central metadata         system. The Hash Allocation Table is used to locate specific         chunks the same way a Distributed Hash Table would have been         used, but the method for updating the shared Hash Allocation         Table is far more flexible.     -   A method for reliable multicast transmission of chunks that is         enabled as the result of establishing a Rendezvous Group.

Description of Drawings Illustrating Aspects of the Scalable Object System

FIG. 32 depicts a process for weighting servers in an object storage system in accordance with an embodiment of the invention. FIG. 32 shows that the list of server IDs 3201 may be collected from the Ring manager that keeps track of the current set of servers that are active. The servers in the list are put through a process that performs a weighting process 3202 for the servers. In one implementation the weighing process is split into two parts 3203 for servers that handle get chunk operations 3204 and the other for servers that handle put chunk operations 3207. As indicated CPU and memory capacity may determine weightings for the get chunk operations 3204, while disk and memory capacity may determine weightings for the put chunk operations 3207.

Each of these processes yields a table of hash codes (3205, 3208) that are used by the Hash Assignment Table(s). As indicated, the get weightings may be stored in a Get Weighting Table of Hash Codes 3205, and the put weightings may be stored in a Put Weighting Table of Hash Codes 3208.

FIG. 33 depicts a sample assignment of server IDs to rows of a hash table for an object storage system in accordance with an embodiment of the invention. Shown in FIG. 33 is a sample (partial) list 3309 of server IDs. While the example storage system has more than ten storage servers, only the first ten server IDs are shown in FIG. 33 for reasons of space.

An intermediate table 3310 with rows indicating negotiating groups to which each server belongs is also shown. The first row (“1”) corresponds to the first server (server ID “27946418453657386492”) in the sample list 3309 of server IDs. As shown, this first server is a member of negotiating groups numbers 49, 34, 21 and 10. The second row (“2”) corresponds to the second server ID (server ID “369443410833473321068”) in the sample list 3309 of server IDs. As shown, this second server is a member of negotiating groups numbers 33, 70, 9, 50, 93, 38, 85 and 34.

After all of the weighting is assigned, the hash values may be organized into hash rows of a hash allocation table (HAT) 3311. There are numerous algorithms that can perform the hash organization in this fashion. Consider, for example, negotiating group 10 which corresponds to hash row “10” in the HAT 3311. As seen in FIG. 33, hash row “10” includes server ID “27946418453657386492” which is the first server ID in the sample list 3309 and server ID “29497889711560748519” which is the eighth server ID in the sample list 3309. Notice that both the first row and eighth row in the intermediate table 3310 include a “10” which indicates that the first and eighth server IDs are both members of the tenth negotiating group.

FIG. 34 depicts processing of a chunk hash ID to determine a set of server IDs in an object storage system in accordance with an embodiment of the invention. In FIG. 34, a chunk 3401 has its content passed through a cryptographic hash Algorithm 3402 (SHA256, in this example) which generates a cryptographic hash digest 3403 of the content. In the example illustrated, that digest is further processed by a hash algorithm 3404 which reduces the hash to a small number, assuming that the hash algorithm is a cryptographic hash algorithm or of similar high quality to provide for a predicatably uniform distribution of the hash results. In the illustration the small number is represented as 00-99, but is more likely to be a power of 2 that is between 2̂5 and 2̂16. The small-number hash in this example is used to index a table 3405 which contains the lists of servers (server IDs) that are the superset of the servers that are designated to hold the manifest for the object. In this example, the table 3405 would have one hundred rows due to the range of the hash algorithm 3404.

In an alternative implementation, each row of the table could represent a range of the cryptographic hash results. Indexing the table in this fashion would allow more precise balancing of the table at the cost of increasing the cost of searching it. Any implementation may consider those tradeoffs for itself based on current processing and memory capacities. Either method of indexing is compatible with the presently-disclosed solution.

Glossary of Terms

The following select definitions are presented to illuminate specific embodiments of the presently-disclosed invention, but they are not necessarily meant to limit the scope of the invention.

Arbitrary Chunk ID—A Chunk Identifier supplied by an outside entity, such as an HDFS namenode, to identify a specific Chunk. This identity has no known relationship with the chunk payload, but as with any Chunk ID will not be re-used to reference different chunk payload for at least twice the lifetime of the chunk.

Better Response—A Better Response for the same chunk is “better” if the combined Timestamp and Source fields represent an “earlier” response, or if the version of a chunk is later (more recent).

CCOW™ (Cloud Copy on Write™)—CCOW is an object storage system created by Nexenta Systems that could utilize the present invention. One of the defining characteristics of CCOW is that the chunks are:

-   -   Created once.     -   Accessed and replicated multiple times.     -   Never updated.     -   Eventually deleted.

Chunk—A “chunk” is typically a description for a subset of an object. That is, an object is typically split into multiple chunks. In other object storage systems that we have studied, the chunks of an object and the metadata of an object are treated as two separate types of data and are treated differently and stored differently. In accordance with an embodiment of the present invention, the metadata can be accessed as either metadata or as a chunk. Thus, the term chunk can refer to any subset of the metadata or data for a version of an object, without regard to how uniform or divergent the handling of metadata is from data in a specific storage system.

Chunk ID—The identifier of a Chunk which can never refer to different chunk payload for a period that is at least twice as long as the lifespan of a chunk. This is the Content Hash ID in an exemplary embodiment, but it can be an Arbitrary Chunk ID supplied by a centralized metadata system (such as an HDFS namenode) in some embodiments of the present invention.

Chunk Manifest—A Chunk which holds Chunk References but which is not a Version Manifest, but instead represents a nested portion of the full Chunk Reference list for a Version Manifest. It is referenced by its Chunk ID in the parent Version Manifest or Chunk Manifest.

Chunk Put—A Chunk Put is an operation or a PDU which transfers the payload and metadata of a chunk to the Rendezvous Group. See ‘Chunk Put Proposal’ for an explanation of how these terms may be viewed either as an operation or as a PDU.

Chunk Put Proposal—An operation, or a PDU (depending on which layer the reference is used in) which proposes a Chunk Put using reserved bandwidth. When discussing the algorithm for assigning persistent storage responsibility, this is an abstract operation. When discussing the specific protocol used to implement that collaboration, this is a PDU.

Content Hash ID—The Content Hash ID is a cryptographic hash (typically SHA256 or other suitable hash) that represents a digest of the chunk payload (after optional compression).

Designated Servers—In a preferred embodiment, the set of servers responsible for the long-term storage of a chunk. The designated server list is a subset of the Negotiating Group. A server may be the designated server for a set of chunks.

Distributed Hash Allocation Table—A table used in the preferred embodiment implemented on multiple servers. It maps a range of Hash IDs to a Multicast Address Set and an enumerated list of designated members. When non-IGMP transport protocols are used it would also enumerate other classes of members.

Failure Domain—A domain where storage servers are deployed where there is increased risk of concurrent failure of multiple servers. Therefore, it is undesirable to rely on independent replicas of a given chunk to be stored within the same failure domain. For example, two storage servers that share a single power source would not provide two independent replicas. A single failure could lose access to both replicas.

Gateway Servers—In a preferred embodiment, the set of servers responsible for making special replications of chunks that do not get added to the Chunk's replication count. These servers are used as the front-end or gateway to either archival storage or as gateways to a remote cluster that shares knowledge of assets. The gateway server list is a subset of the Negotiating Group.

Hash Allocation Table—A collection of mappings for ranges of Hash IDs to a Negotiating Group of storage servers and a Multicast Address that can be used to reference them. All servers in the storage cluster have identical Hash Allocation Tables, or at least Hash Allocation Tables that have no conflicting rows. The Hash Allocation Table may be considered to be a specialized form of a Distributed Hash Table. Chunks are found in the Hash Allocation Table in the same manner that they would be found in a Distributed Hash Table. The Hash Allocation Table is specialized in that it is maintained by distributed editing rather than by being generated on each server using the Distributed Hash Table from the same set of inputs.

Hash ID—The Chunk Hash ID is a cryptographic hash (typically SHA256 or other suitable hash, such as SHA-512 or SHA3) that represents a digest of the chunk's data or of the Object Name Identifier (also known as the Name Hash ID—typically a string of encoded text). In the present disclosure, this is used to control the selection of the Negotiating Group for a chunk, either the Name Hash ID or the Content Hash ID.

Jittered Delivery—Jittered delivery is where not all recipients will receive their copies at the same time. Some recipients will receive a chunk when it is first broadcast while other recipients will receive a chunk during a later “retry” to insure that a sufficient number of the targeted recipients have received their copies.

Keep-Alive Ring—A Keep-Alive Ring is a distributed software component which enables a distributed set of servers to determine the set of servers which have joined the ring and which are still capable of communicating with the ring. Typically, when a departure or addition is detected, each member of the ring will notify its local clients of the new or departed servers.

Most Frequently Used (MFU)—A data item is tagged with a frequency counter that marks how frequently it is referenced within a given time window. MFU may be combined with Most Recently Used to determine if a data item should be retained on a queue or deleted from a queue.

Most Recently Used (MRU)—Each time that a data item is referenced, it may be tagged with a timestamp (many implementations are possible). Each time that the queue of data is referenced, the queue may be examined for a combination of MFU and MRU to determine which data items (e.g. chunks) should be removed from a queue.

Multicast Address—A Multicast Address is a network address that enables a message to be sent to a group of destination endpoints. In most embodiments of the present invention, this will be an IP multicast address.

Multicast Address Set—A set of Multicast Addresses that enables a message to be sent to all members of a matching group. The set can be represented as a two-dimensional array. One dimension represents different parallel networks that can reach the same storage servers but over distinct network resources. For each physical network that the storage servers are attached to, one of the multicast addresses in a Multicast Address Set is to be used. The second dimension allows definition of subsets of the Negotiating Group. For example a second multicast address can be created for each Negotiating Group that is subscribed by servers wishing to receive notification of new named chunks. In the preferred embodiment, the Multicast Address Set is assigned to a Distributed Hash Allocation Table using a configuration object.

Multicast Group Address—A Multicast Group Address is a single address which will direct a packet to be delivered to a group of end stations. Multicast addresses are defined for both Layer 2 and Layer 3 protocols. Ethernet is the primary example of a layer 2 protocol, while IP is the primary example of a Layer 3 protocol.

Multicast Rendezvous Group—The Multicast Rendezvous Group is the subset of the Negotiating Group that are selected for either getting copies of an asset (Chunk, Chunk Manifest or Version/Named Manifest) when it is GET or PUT. In a preferred embodiment, the GET membership is the server that has provided delivery of the “Best Response” of the asset. The PUT membership is the set of servers that provided not only optimum storage (e.g., quickest movement to non-volatile storage, but also the best diversity across “Failure Domains”).

Name Hash ID—A Name Hash ID is a Hash ID of the name of an object for a chunk holding the base of the metadata for a version of an object. It is derived from the object name, rather than from the chunk content.

Negotiating Group—A Negotiating Group is the group of storage servers that are collectively assigned responsibility to provide access to Chunks for a specific range of Hash IDs. A Negotiating Group may also be referred to as a Designated Super-Group. Typically the Negotiating Group is found by searching the Distributed Hash Allocation Table. Each range of Hash IDs, which corresponds to a row in the Distributed Hash Allocation Table, has a Multicast Address which can be used to address all members of the group. Alternatively, a central metadata system (such as an HDFS namenode) can specify the membership of a Negotiating Group. The presently-disclosed solution allows virtually unlimited scaling of a storage cluster because no matter how large a cluster is, only the members of the Negotiating Group are relevant to the operations on any specific chunk. Doubling the size of the cluster only requires doubling the number of Negotiating Groups.

Notification Servers—In a preferred embodiment, the set of servers that have requested notification when Chunks with a matching Hash (e.g. an Object) have been updated. These servers are most office client servers or proxies that are on a notification queue that will provide information on updates to previously created Chunks. In the preferred embodiment, this is most frequently used for the hash of the name of an object. The notification server list is a subset of the Negotiating Group.

Payload ACK—A Payload ACK is a PDU sent by the recipient of a Chunk Put message to indicate whether the payload was received successfully.

PDU (Protocol Data Unit)—An encoding of a message used to communicate between peers at the same layer, as in an 051 layered model of network communications.

Persistent Storage—Storage for encoded data that is reasonably expected to survive (be available for retrieval) even across a power outage.

Put Accept—A response to a Chunk Put Proposal that specifies whether the storage server already has the identified chunk, or if not when it could receive it, or when it cannot accept the chunk at this time.

Reception Window—The time period (in microseconds) after the time of the Get Request that contains the Reception Window, when the Requestor will desire delivery of the Get Request.

Relayed ACK—A relayed ACK is a PDU sent from the Chunk Source to the Designated Super-Group which relays one more received Payload ACKs so that every member of the Designated Super-Group can be aware of exactly how many replicas of a specific chunk have been successfully created.

Rendezvous Group—The group of storage servers selected to receive a replica of a chunk during a chosen rendezvous of chunk transmission.

Rendezvous Time Window—A Rendezvous Time Window is a proposal for, or consensus upon, a time window for the delivery of a specific chunk to a Rendezvous Group. This includes a start time, duration and a maximum bandwidth.

Rendezvous Transmission—A rendezvous transmission is a transmission of Chunk content that is multicast to a Rendezvous Group. This is a step in either a get or a put of a chunk.

Relayed Unicast Delivery—Relayed Unicast Delivery is the simulation of a multicast delivery in a network environment where multicast is not allowed by network policies. With Relayed Unicast delivery, the packet is delivered once by the originator to the first member of the Rendezvous Group using a Unicast protocol such as TCP/IP (virtual circuits). Each recipient of the chunk with the Rendezvous Group will remove their server id from the list of recipients and then forward the chunk and recipient list to the next reachable

Service Level Agreements—Contractual arrangements between hosting or Storage as a Service (SAAS) companies and their customers that guarantee the retention of data and the response time for the availability of data.

Shared and Distributed Hash Allocation Table (HAT)—A Shared and Distributed Hash Allocation Table (HAT) is an object instantiated on each storage server, and potentially on Chunk Sources as well, which encodes the mapping of a range of Hash IDs to Distribution Table tuples. This is most likely to take the form of a sorted array of table entries. The methods for allowing safe access to the table while allowing ongoing updates will be implementation specific, but can include a wide variety of techniques for doing so.

Unsolicited Commands—Commands such as get or put that have an urgent and small request. They will typically include the payload as part of the command rather than proposing that the payload is sent and waiting for round trip times to confirm the delivery request, the payload is included with the command. Unsolicited commands are sent using unsolicited bandwidth. Unsolicited bandwidth is reserved stochastically for an anticipated probable maximum, rather than being reserved for specific transfers.

Version Manifest Chunk—A chunk which holds the root of metadata for an object and which has a Name Hash ID. The term used for such chunks in the Nexenta CCOW storage system is Version Manifest.

Volunteer Servers—In a preferred embodiment, Volunteer Servers are those servers that volunteer to make extra copies of a Chunk, in anticipation that the Chunk will be requested in the near future. Analogous to the Adaptive Replacement Cache which is used in ZFS storage, in one embodiment, the Volunteer servers use a combination of Most Recently Used (MRU) and Most Frequently Used (MFU) Chunks to determine which chunks are maintained in their local storage. The copies of Chunks that are placed in these servers are not counted as Designated Copies. The Chunks in these servers are normally held for relatively short periods of time and in preferred embodiments can be deleted almost at will. The only exception to this is, if the Chunk has not yet had a sufficient number of Designated copies committed to long-term storage.

III. Multicast Collaborative Erasure Encoding

The present section describes systems and methods for multicast collaborative erasure encoding. The multicast collaborative erasure encoding taught in this section may be applied for an object storage system that relies upon unreliable multicast datagrams for reliable transfer of payload within the cluster. An exemplary object storage system is the scalable object storage system described above in Sections I and II.

The present disclosure provides methods and systems for multicast collaborative erasure encoding of stored data that may be utilized with an object storage system that employs multicast replication. The multicast collaborative erasure encoding advantageously allows for protection against loss of individual drives or servers using less storage than would be required to provide the same protection with full replicas.

Note that the present solution is applicable to different types or erasure encoding, including XOR parity encoding using RAID Zn algorithms and Reed-Solomon encoding. The discussion of FIGS. 37 and 38 focuses on XOR parity encoding for purposes of clarity in explanation.

Conventional Erasure Encoding

Conventional erasure encoding encodes storage assets in slices across N devices or servers, where the original content can be restored from a lesser number M (M<N) of the data slices. For example, if M=8 and N=10 (“8 of 10” encoding), then each of N=10 slices contains a different 1/M=1/8 of the contents of the chunk. The N=10 slices in total store content the size of N/M=10/8 times the chunk size. This example of 8 of 10 encoding protects against the loss of two slices.

Conventional erasure encoding reduces both network traffic and raw storage capacity required to store an asset at the cost of greater computational work being required on both put and get. Without erasure encoding, a conventional object cluster can only protect against the loss of two servers by creating three replicas. This requires that the content be transmitted over the network three times.

With erasure encoding, a minimum of M slices, each holding at least 1/Nth of the total content, must be transmitted, resulting in M/Nths of the payload size. This represents a considerable savings in network bandwidth. However, this is still more than the single transmission required to create N replicas as previously described for the “Replicast” transport protocol.

Conflict Between Multicast Replication and Conventional Erasure Encoding

Unfortunately, there is a conflict between the operations of multicast replication (for example, using the above-described “Replicast” protocol) and conventional erasure encoding. While multicast replication delivers the same content to each storage server in a series of multicast datagrams sent to a negotiated Rendezvous Group in a Rendezvous Transfer, conventional erasure encoding creates N different slices of the object on N different storage servers. This conflict is a problem that prevents conventional erasure encoding to be applied directly in an object storage system employing multicast replication.

Multicast Collaborative Erasure Encoding

The present disclosure provides a technique that solves this problem. The presently-disclosed technique extends the multicast replication protocols to allow for the reliable creation of erasure-encoded slices of a chunk, while retaining the multicast protocol's advantageously efficient single transmission of a new chunk as a single complete entity. This presently-disclosed technique is referred to as multicast collaborative erasure encoding.

Furthermore, while conventional erasure encoding requires that a single entity perform the calculations to divide any given chunk into N slices, the presently-disclosed technique of multicast collaborative erasure encoding distributes this computational load to the receiving storage servers. This provides two advantages: first, the receiving storage servers do the calculations in parallel; and second, the calculations to erasure encode a chunk may be deferred. These advantages are highly desirable because there are both computational and latency penalties when retrieving erasure encoded content.

Note that, when assigning responsibility for holding specific stripes of the erasure encoding to specific servers, a preferred embodiment of the presently-disclosed solution would not assign more than one stripe to storage servers in a single failure domain. This is because the resources within a failure domain, by definition, have potentially correlated failures. The goal of erasure encoding is to preserve the chunk if M of N stripes are retained; hence, storing multiple stripes on devices that are prone to have correlated failures is contrary to the data protection strategy. The assignment of no more than one stripe to storage servers in a single failure domain is a prudent feature, but not an absolute requirement, of the presently-disclosed solution.

Regarding deferred erasure encoding, because there is a latency penalty when accessing erasure-encoded chunks, it can be preferable to store new content without erasure encoding and only perform the erasure encoding at a later time once the probable demand to access the chunk has diminished. In other words, it is highly desirable to first encode a chunk as a full chunk at the storage servers and retain this full encoding of the chunk while the chunk is most likely to be accessed; subsequently, when the chunk may be viewed to be in “cold storage,” the chunk may erasure-encoded into slices at the storage servers to save storage space.

For most object cluster services, the oldest portion of the stored data is unlikely to be retrieved. For example, consider a typical e-mail inbox. The vast majority of storage is required for messages that are more than a week old, but reading e-mail messages that are more than a week old is very rare. So applying erasure encoding to the older messages is desirable, especially if new messages can remain fully encoded for speedy retrieval.

The presently-disclosed solution has the further advantageous aspect that the chunk does not have to be redistributed to enable erasure encoding of it. As a result, the older portion (older chunks) of the stored data may be erasure encoded in a deferred manner, while the newer portion (newer chunks) may remain full-chunk encoded. This aspect further saves on network bandwidth.

The presently-disclosed solution has yet a further advantageous aspect in that the re-encoding of whole chunks to erasure-encoding slices leaves unmodified the chunk references held in the encoding of the object metadata. This aspect is advantageous in further saving both computational resources and network bandwidth.

Iterative Collaboration Using Multicast Roll Calls and Responses

The presently-disclosed solution uses multicast messaging to collect the current state of how a specific chunk is stored in the object cluster. The solution then uses multicast messaging to iterate towards a desired state through a series of steps.

FIG. 35 is a flow chart of a method 3500 of erasure encoding of a chunk that is stored in an object storage system with iterative collaboration using multicast roll calls and responses in accordance with an embodiment of the invention. The method 3500 may be performed within an object storage system with multicast replication.

i) Erasure-Encoding Roll Call

Per step 3502, an initiating node multicasts an erasure encoding “roll call” request to the group responsible for the chunk to be erasure encoded. In the above-described object storage system with multicast replication, the initiating node may be a storage server of the object storage system. The group responsible for the chunk may be the negotiating group for the chunk, where the negotiating group is identified using a cryptographic hash identifier of the chunk. However, alternate methods of identifying an existing multicast group for a chunk may be used instead.

In other words, in accordance with an embodiment of the invention, when a chunk has been identified as a candidate for erasure encoding, a multicast “Erasure-encoding roll call” message may be sent to the Negotiating Group for that chunk. This message preferably includes an identifier of the Negotiating Group, an identifier for the Chunk to be erasure encoded, the specific erasure encoding algorithm to be used, and a unique identifier of the Roll Call. One embodiment of the Roll Call identifier is formed by concatenating a timestamp and the IP address of the requester. Alternately, the Roll Call identifier may be a concatenation of a sequence number and the source IP address.

ii) Roll Call Inventory Response

Per step 3504, each node in the group receiving the request multicasts a “roll call inventory” response to the “roll call” request to all the other nodes in the group. The roll call inventory response message identifies: a) the roll call message being responded to; b) the specific storage node that is responding; c) whether this storage node has stored in it a whole replica of the specified chunk; and d) which, if any, erasure encoded slices this storage node has (or has begun building) for this specified chunk. In other words, each roll call inventory response from a node enumerates the encodings of the chunk (whole and/or specific erasure encoded slices) that are stored at that node.

In other words, in accordance with an embodiment of the invention, each recipient of the erasure-encoding roll call request responds with an erasure-encoding chunk inventory multicast message which it sends to the same Negotiating Group. This roll call inventory response may preferably include:

the echoed identifier of the roll call request;

the identity of the responding object storage server instance;

the identifier of the chunk being queried; and

how the identified chunk is encoded on local storage by this instance.

In an exemplary implementation, “how the chunk is encoded on local storage” may be: not at all; a whole copy; or slice number n of N according to the specified erasure-encoding algorithm, which divides the chunk into a total of N slices.

In exemplary implementation, in addition to a roll call inventory response, a node of the group may further respond to a roll call request by multicasting an offer to voluntarily compute a slice for CPU-challenged storage nodes. Such an offer may include whether the whole chunk was already stored on the offering node, and a commitment as to how quickly a requested slice could be computed. In this case, a node that has assigned itself the responsibility to compute a slice may elect to contact the volunteering server if it is committing to provide a copy earlier than the storage server could compute the answer itself. Such a decision may consider recent levels of network congestion; the fact that another node can compute a slice more quickly is irrelevant if the network transfer cannot be completed promptly.

iii) Collection of Roll Call Inventory Responses

Per step 3506, every node in the group collects “roll call inventory” responses that respond to the “roll call” request. By having every node in the group collect the roll call inventories, every node has the information needed to evaluate the collective inventories within the group to formulate a same set of actions. While every member of the group collects the full set of inventory responses that it receives for any given roll call request, a dropped message may be simply ignored without a retransmission request.

Note that a storage server may receive Roll Call Inventory responses to a Roll Call request that it did not hear. Embodiments are free to either ignore such messages, or to retroactively infer reception of the Roll Call request by not only collecting the response but responding to it as well.

iv) Evaluation of Roll Call Inventory Responses and Determination of Subset of Actions to be Performed by Individual Node

Per step 3508, every node in the group evaluates, in parallel, the collected roll call inventory messages to determine the set of actions that are required. The logical evaluation by a node may begin once roll call inventory response messages have been received from all members of the group, or after a predetermined time has elapsed that is sufficient such that no more responses can be reasonably expected. In an exemplary implementation, the set of actions determined may include: multicasting the whole chunk to create new replicas at other nodes in the group and/or encoding (and potentially transferring) slices of the chunk. The evaluation depends upon the collective roll call inventories from the nodes in the group. The evaluation depends on which nodes in the group already stores a whole replica of the chunk and what slices already exist, or are already being constructed, at the nodes in the group.

In other words, each member of the group evaluates the collected responses, determines the collective action required (if any), and assigns itself a portion (if any) of that work. This assignment is based upon parallel evaluation that orders both the tasks to be done and the available storage nodes. Any ordering algorithm is acceptable as long as all members of the nodes will assign the same work to the same storage nodes without the need for active collaboration.

Per step 3509, every node in the group determines a subset of the set of actions to be performed by itself. The subset of actions assigned to a node is determined in a same agreed-upon manner at each node in the group. The subset of actions for a particular node may depend upon the particular node's place in the ordering of the nodes in the group. The ordering may be, for example, a sorted order based on a node identifier.

In an exemplary implementation, the analysis of the collected roll call inventory responses and the determination of the subset of actions to be performed by a node are described further below under the section “Analysis of Collected Inventory Responses.”

v) Performance of Subsets of Actions by Nodes in the Group

Per steps 3510-n, for n=1 to Ng, where Ng is the number of nodes in the group, the nth node in the group performs an nth subset of actions. The subset of actions to be performed by a node being determined in step 3509 as discussed above. As mentioned above, the actions may include multicasting the whole chunk to create new replicas at other nodes in the group and/or encoding (and potentially transferring) slices of the chunk. (Note that it is possible that a subset of actions may be empty, in which case the node corresponding to that subset is not assigned to perform any action.)

vi) Selection of Pseudo-Random Times for New Roll Call Request

Per steps 3512-n, for n=1 to Ng, when a node completes its assigned subset of actions, a time may be selected for a new roll call request. The time may be selected pseudo-randomly to distributed the selected times amongst the nodes in the group. At the selected time, the new roll call request may be multicast from the node to the group. However, if an erasure-encoding roll call for the same chunk is received before the selected time, then the multicasting of the new roll call request at the selected time will be pre-empted for the node.

In other words, after completing its work pursuant to a prior Erasure-encoding roll call, a storage node will pseudo-randomly select a time to issue a new Erasure-encoding roll call for the chunk. The new Erasure-encoding roll call for the chunk will be pre-empted should an Erasure-encoding roll call for the same chunk be received before the node's own new Erasure-encoding roll call is issued.

The above-described pseudo-random mechanism that distributes the issuance of new roll call requests advantageously prevents multiple nodes from flooding the available network at the same time.

vii) Next Iteration Initiated by New Roll Call Request

Upon a new roll call request being sent by any one of the nodes, then the method 3500 loops back to step 3514 and a next iteration is performed. In this way, the method collaboratively iterates in a dynamic manner to a desirable state. In accordance with an embodiment of the invention, the procedures of the presently-disclosed solution converge upon a stable encoding of the chunk, either as whole replicas, or as erasure-encoded slices. Lost replicas or lost slices may be replaced through background scanning of the multicast group.

Note that the method 3500 depicted in FIG. 35 uses a pseudo-random mechanism to select in an ad-hoc manner the executor of the next roll call. An alternate embodiment may utilize a deterministic way of, effectively, determining the master of the next iteration. For example, one deterministic technique would be to issue the next roll call from the first node ID in a sorted list of node IDs of the nodes that take part in the iteration. Other pseudo-random or deterministic techniques may be used in other implementations.

Comparison with Unnamed Chunk Get Sequence with Cluster Consensus

Note that, the sequence of the erasure-encoding roll call and the erasure-encoding chunk inventory messages has some similarities with the Unnamed Chunk Get Sequence with Cluster Consensus in the above-described replicast protocol. However, there are the following differences.

First, the goal is to determine what actions are required, rather than to get an existing replica. An Erasure Encoding Roll Call may lead to creation of new erasure-encoded slices and making whole replicas removable. However, this is a goal achieve over an iterative collaboration. The process by which a Unnamed Chunk Get results in a Rendezvous Transfer in the base Replicast protocol is far more direct.

Second, the storage nodes therefore have less discretion to simply ignore the unsolicited message when they are backed up (as they can with Unsolicited Gets), and therefore more tolerance must be granted for time-delay Inventory responses.

Analysis of Collected Inventory Responses

According to one embodiment of the invention, in logically analyzing the full set of inventory responses, each storage server may diagnose one of the following conditions.

a) There are insufficient replicas (whole or erasure encoded slices) of this chunk. Replication procedures as defined for the Object cluster are to be applied to create more whole replicas (for example, if the storage goal is to store multiple whole replicas of the chunk) or create further erasure-encoded slices (for example, if the storage goal is to store erasure-encoded slices).

b) There are sufficient whole replicas, but the replication count R for slices is less than a target number of N erasure-encoded slices. In this case, the selection algorithm may assign responsibility to generate multiple slices to the servers already holding the chunk, and then having those servers replicate the extra slices to their selected homes (i.e. to the storage servers of the negotiating group selected to hold those slices). In this way, the replication count R for slices may be raised to the target number of N.

c) There are missing slices for this chunk such that the replication count R for slices is less than the number M needed to reconstruct a whole chunk, and this storage server has a whole replica of the chunk. In this case, this storage server may generate an enumerated (ordered) list of the responding servers. The enumeration may first list (at lower ordinal numbers) only those servers that currently have the whole chunk stored, and then enumerate (at higher ordinal numbers) the servers that do not currently have the whole chunk but may obtain it. The ordering may also factor in the available capacity and latency of the storage servers. Sorting within each category (whole chunk stored, or do not currently have the chunk) may be based upon the network addresses of the storage servers, for example. Other enumerations and sortings may be used, so long as the same algorithm is applied for all members of the group.

If the storage server is at ordinal number n in the enumerated list, then it may assign to itself the action or task of creating the nth slice of the chunk (the slice being generated as a derivative of the whole chunk). Furthermore, if there are also insufficient copies of the whole replica of the chunk, then the first member of the group that does not have a whole replica may initiate a replication of the whole chunk to the negotiating group.

d) All slices of the chunk are represented in the collected responses. When this condition occurs, the original data holding the whole chunk encoding may be deleted by this storage instance.

e) There are insufficient slices and no whole representation represented. In this case, the best member of the cluster (the one that can perform the task quickest) should initiate a Get of the chunk, resulting in it storing the entire chunk.

According to another embodiment of the invention, the state diagram of FIG. 36 may be utilized in the analysis of the collected roll call inventory responses and the determination of the subset of actions to be performed by a node. The state diagram illustrates the life cycle of a single chunk as it may be encoded as replicas and/or slices in accordance with an embodiment of the present invention. The state diagram further shows how loss of stored replicas or slices are dealt with.

As depicted, the state may depend on the goal for the storage of the chunk. In an exemplary implementation, a first storage goal 3601 may be storing multiple whole replicas of the chunk, and a second storage goal 3611 may be storing erasure-encoded slices of the chunk. As described above, for example, the first goal 3601 may be applied to frequently accessed chunks, while the second goal 3611 may be applied rarely accessed chunks.

For a chunk that has the first storage goal 3601, there may be two different states, where the state is determined based on the roll call inventory responses.

A first state 3602 under the first storage goal 3601 may be a stable state where it is determined that there are sufficient whole replicas encoded and distributed within the group such that the chance of losing all replicas is acceptably remote.

A second state 3604 under the first storage goal 3601 may be a state where it is determined that there are insufficient whole replicas encoded and distributed within the group. In this case, the chance of losing all replicas (i.e. going to state 3622) is unacceptably high. As such, a replication procedure as defined for the object cluster may be applied to increase the number of whole replicas.

In the replication procedure, one of the nodes with a whole replica may elect itself to replicate the chunk to more nodes of the group. In an exemplary implementation, every member of the group elects itself with a pseudo-random delay. Hence, all but one member will see another replication already initiated, and hence cancel its own replication attempt before it is launched.

For a chunk that has the second storage goal 3611, there may be four different states, where the state is again determined based on the roll call inventory responses.

A first state 3612 under the second storage goal 3611 has insufficient erasure-encoded slices, but it has whole replicas still available within the group. Because there are insufficient slices, the whole replicas are not yet eligible for deletion. For example, this state 3612 may be entered when the storage goal changes from the first goal 3601 to the second goal 3611.

In this state 3612, in an exemplary implementation, the action determination algorithm may assign responsibility to generate multiple slices to servers already holding the whole chunk and/or to servers not yet holding the whole chunk. In the latter case, the whole chunk may be first replicated to the servers. The responsible servers may generate further slices (which are basically blobs derived from the whole chunk) and then replicate the further slices to their selected nodes.

Thereafter, roll call requests may continue to be issued (after pseudo-random delays) as discussed above in relation to FIG. 35, and the slice building may thus continue until sufficient slices are available in the group. Once sufficient slices are available in the group, the state may change to the second state 3614.

A second state 3614 under the second storage goal 3611 has sufficient erasure-encoded slices. This state also has whole replicas still available within the group, but these whole replicas are now eligible for deletion. When there are no whole replicas left, the state for chunk encoding transitions to the third state 3616 under the second storage goal 3611.

In this third state 3616, there are sufficient erasure-encoded slices and no available whole replicas. If slices are lost such as the slices are no longer sufficient, then the state for chunk encoding may transition to a fourth state 3618 under the second storage goal 3611.

This fourth state 3618 may be a state where it is determined that there are insufficient erasure-encoded slices and no whole replicas remaining in the group. In this case, the chance of losing too many slices (i.e. going to state 3624) is unacceptably high. As such, a slice rebuild procedure is put in process. Once sufficient slices are available in the group, the state may change back to the third state 3616.

Tolerance for Lost Roll Call Inventory Responses

In an exemplary implementation, the multicast communications used for Erasure Encoding Roll Call messages and Inventory responses is made effectively reliable through the use of a congestion control algorithm such as above in relation to multicast replication (replicast).

However, it may be noted that there is no permanent harm should an incomplete set of Roll Call Inventory messages. The worst that can happen is that work assignments include creation of slices that were actually already stored in the cluster or that multiple storage nodes will assign themselves the same work. While these mistaken steps are regrettable, they will not harm the object cluster.

Whole replicas are only eligible for deletion when the collected set of Inventory responses shows a complete set of slices to be available and/or excessive whole replicas are available. The absence of data cannot enable deletion of content that would not have been deleted anyway.

Embodiments of the present invention therefore merely have to ensure that dropped messages are rare. The present invention is tolerant of individual drops of Roll Call Inventory messages.

Stateless Get Extended for Erasure Encoding

To be compatible with erasure encoding, the replicast protocol for responding to an Object Get request may be extended such that, in responding to an Object Get request, a storage instance may indicate that it only has slice n of N with erasure encoding algorithm X for Chunk Y. In other words, the processing of a multicast Get Request is extended to allow a Get Response to additionally report that a specific slice of a chunk is available from this source, rather than the whole chunk. This response would still indicate when the data being offered could be made available.

The Get Responses must be evaluated to determine from which sources to schedule Rendezvous Transfers. The above-described multicast replication (replicast) protocol already describes processes (client consensus and cluster consensus) for selecting the “best” response to an Object Get request. The process for reaching a consensus may be extended by adding the following rules or preferences.

Get responses with whole encodings of the whole chunk are generally preferred over Get responses with slices of the chunk. However, if slices can be fetched iteratively and a whole replica reconstructed before an existing whole chunk would be available, then the Get Accept message may specify a rendezvous transfer with the server that reconstructs the whole replica. The most common case here will be when there is no whole copy of the Chunk available nearby in the Object Cluster, but it is possible that a whole chunk could be available from an archive service or a remote segment of the Object Cluster. In this case, it may be predictably faster to rebuild from local slices rather than to start a remote fetch of the whole object.

If slices are used, they are preferably retrieved from the specific servers holding them. Missing slices may be regenerated according to the technique discussed in the “Distributed Slice Regeneration” section. The reassembly process may be then applied by the server that issued the Object Get request. The chunk reassembled from erasure-encoded slices is then subject to normal chunk validation procedures, including validating that its content still matches its cryptographic hash.

Keeping track of the chunks that are subject to erasure encoding (and the chunks that are not) may be done in metadata.

Note that when a storage instance leaves the Negotiating Group, a Roll Call request should be issued for each Chunk that the departed instance potentially stored. This would be a normal part of the replication process triggered whenever a storage instance departs.

Deferred Erasure Encoding

The presently-disclosed solution does not require a chunk to be erasure encoded when it is initially put to the object storage cluster.

Any retrieval of a chunk that has been erasure encoded will require waiting on more storage nodes and require the extra step of assembling the content. Because of these unavoidable penalties, it will be frequently advantageous to initially store a chunk with whole replicas and defer the storage space savings of erasure encoding until a later time when the retrieval demand for the specific chunk has diminished. Storage systems typically see a rapid drop in the probability that a given chunk will be accessed as the chunk ages. For example, a chunk holding portions of today's email will have a higher probability of being read than a chunk holding month-old email.

The presently-disclosed solution includes a transition from encoding a chunk as whole replicas, to creating slices in addition to the whole replicas and then allowing for eventual deletion of the whole replicas.

Distributed Slice Regeneration (Distributed Recovery of Lost Stripe)

FIG. 37 depicts a conventional method of recovery of a lost stripe from a parity stripe. As shown on the left of the diagram, the chunk may be stored in multiple stripes: S1; S2; S3; and S4, where in this example four stripes are used. Other numbers of stripes may be used in a practical implementation. In addition, a parity stripe S1̂S2̂S3̂S4 is stored, where the A symbol represents a bit-wise XOR operation. Note that the terms “slice” and “stripe” are used in a largely interchangeable manner in the present disclosure.

If, for example, the S4 stripe is lost or otherwise not obtainable, then the chunk may still be recovered using the parity stripe. The operation to recover the S4 stripe is represented by: S1̂S2̂S3̂(S1 ̂S2̂S3̂S4)=S4.

FIG. 38 depicts a method of distributed recovery of a lost stripe from a parity stripe in accordance with an embodiment of the invention. As shown on the left of the diagram, the chunk may be stored in multiple stripes: S1; S2; S3; and S4, where in this example four stripes are used. Other numbers of stripes may be used in a practical implementation. In addition, a parity stripe S1̂S2̂S3̂S4 is stored, where the A symbol represents a bit-wise XOR operation.

If, for example, the S4 stripe is lost or otherwise not obtainable, then the chunk may still be recovered using the parity stripe. However, the operation to recover the chunk is different from the conventional method of recovery.

As shown in the diagram, the recovery calculations are broken down into portions that require different subsets of the entire chunk to be assembled. In the example depicted, a first portion of the recovery calculation is performed at a first node that performs the operation S1̂S2=(S1̂S2), and a second portion of the recovery calculation is performed at a second node that performs the operation S3̂(S1̂S2̂S3̂S4)=(S1̂S2̂S4). A third portion of the recovery calculation may then be performed from the results of the first two portions by the operation (S1̂S2)̂ (S1̂S2̂S4)=S4. The third portion may be performed at a third node (or at one of the first two nodes).

Advantageously, the end result is that the rebuild of the slice may be completed in less time. This is because more nodes and network links may be utilized in parallel.

Further description of details relating to distributed slice regeneration is as follows.

Note that when the erasure-encoding algorithm has the characteristics that the decoding steps may be performed in varying order, the present solution can optimize the processing of rebuilding a lost stripe of a chunk.

Note also that RAID protection of objects may be implemented using the present solution of erasure encoding. For example, replication with two additional whole copies may be described as erasure encoding with M=1 (a single slice needed to reconstruct the whole chunk; i.e. the slice is the whole chunk) and N=3 (three replicas stored), giving an encoding rate of M/N=1/3.

As an example of RAID protection, RAID 5 (distributed parity) may be described as erasure encoding with, for instance, M=4 (four slices needed to reconstruct the whole chunk) and N=5 (five slices stored), giving an encoding rate of M/N=4/5. More generally, M=N−1 for RAID 5.

As an example of RAID protection, RAID 6 (distributed parity with two parity blocks) may be described as erasure encoding with, for instance, M=4 (four slices needed to reconstruct the whole chunk) and N=6 (six slices stored), giving an encoding rate of M/N=4/6. More generally, M=N−2 for RAID 6.

Consider an exemplary implementation where the data is striped over N data stripes, with 1, 2 or 3 parity stripes. The first parity stripe is referred to as P. It is a simple parity of the data stripes. The optional 2^(nd) (Q) and 3^(rd) (R) stripes are also calculated from the data stripe, but use a more complex algorithm.

When a single data stripe has been lost, it can be rebuilt by XORing the surviving data stripes with the P stripe. For example, if there are 7 data stripes, and stripe 6 has been lost, then each byte in stripe 6 can be rebuilt with the formula:

S6=S1̂S2̂S3̂S4̂S5̂S7̂P

Because P is S1̂S2̂S3̂S4̂S5̂S6̂S7 the result XORing with the surviving data slices is S6.

In a conventional implementation, the rebuilder fetches all six surviving data stripes and the Parity stripe to rebuild. However, in a networked rebuild, this requires a single storage node to receive all of the surviving stripes and the parity stripe. Effectively the size of the entire chunk must be received to re-create a single lost stripe.

Because lost stripes are relatively rare, a larger concern is for the latency in rebuilding a lost stripe, rather than for the total volume of network traffic. Because the typical chunk is retrieved many times for each time it must be rebuilt, the impact of rebuild traffic on overall network load will be light. However, reducing the rebuild time makes the storage cluster more robust. The purpose of protecting against the loss of multiple slices is to protect against the loss of one or more additional slices before the lost slices are reconstructed. The risk of losing a chunk is therefore directly proportionate to the time it takes to restore a single lost slice.

The present solution shortens the time required to reconstruct a single lost slice by performing the XOR operations in parallel, as follows:

-   -   The set of surviving slices and P are paired. One member of each         pair sends its stripe to the other. The receiving member XORs         its stripe with the received stripe. If there is an odd number,         the “odd man out” conceptually sends to itself and XORs with all         zeroes (i.e. it just declares itself to be ready for the next         round, no real work is required).     -   This continues with the set of nodes that received a stripe,         they are paired and one sends its accumulated XORred stripe to         its partner.     -   Eventually this results in a single copy which has XORred the         entire set, and re-created the lost slice.

For Example:

-   -   The surviving slices are S1,S2,S3,S4,S5,S7. Slice S6 will be         recovered using the P Slices which was created with the content         S1̂S2̂S3̂S4̂S5̂S6̂S7.     -   Step one in parallel do:         -   S1⊕S2     -   (S2 is sent to holder of S1, which XORs them together),         -   S3⊕S4         -   S5⊕S7

And do nothing immediate with Slice P (odd man out).

-   -   Step two, in parallel do:         -   (S1⊕S2)⊕(S3⊕S4)         -   (S5⊕S7)⊕P     -   Step 3:         -   ((S1⊕S2)⊕S3⊕S4))⊕((S5⊕S7)⊕P)

Which yields S6.

Because all three operations in the first phase are performed in parallel, as are the two operations in the second phase, the pipeline delay is the transmission time of 3 slices. This compares favorably to a delay of 7 slice-transmission-times for the non-distributed rebuild (or 4 vs 8 if a final copy of the restored S6 is included). This assumes that the storage nodes have symmetric transmit and receive capabilities, and therefore a single node cannot receive two stripes “at the same time” without slowing transmission of each of them down. This recovery process can also be accomplished by any reversible algorithm that can be decomposed into steps which can be performed in parallel on loosely coupled processors.

Given the pairing-off process for distributed regeneration of a slice, the optimal erasure encoding for a slice would have the number of slices (N) be a power of 2.

Distributed Chunk Verification

Each slice of a chunk is protected by some form of error detection separate from the cryptographic hash verification available for the entire chunk.

One method of doing so is to simply apply the same cryptographic hash algorithm to each slice of the chunk. While convenient, this is actually computational overkill. The only requirement for slice error detection is error detection. There is no need for distributed de-duplication or prevention of spoofed content for slices, only for whole chunks.

Individual storage nodes can perform periodic scrubs on stored slices using the slice error detection field. In addition, background object replication tasks can validate that there are sufficient slices of a chunk still intact on a sufficient number of storage nodes. However, to protect against storage nodes mistakenly storing the wrong data for a slice of a chunk, it is desirable to periodically validate that cryptographic hash of the entire chunk.

The present solution does so without requiring the whole chunk to be assembled as follows:

-   -   The data is sliced so that the first 1/Nth of the chunk is         placed in the first slice, then next 1/Nth in the second slice,         etc. Traditional RAID algorithms rotate the encoding of slices         assuming that the size of the data is variable and to evenly         spread retrieval work across the slices. Those factors are not         relevant for a chunk, which is always retrieved as a whole     -   The storage node holding the first slice begins a cryptographic         hash calculation of the data held in the first slice. When the         storage node completes passing over the data it holds, it         snapshots the cryptographic hash calculation, and sends a         serialization of the cryptographic hash calculation to the         storage node holding the second slice of the chunk. The snapshot         is the state of the cryptographic hash computation which         includes the state of intermediate hidden variables in the         cryptographic hash engine, which are preserved and transmitted.     -   The storage node holding the second slice re-initializes the         cryptographic hash engine with the serialized snapshot, then         applies the cryptographic hash algorithm to its payload. It then         snapshots the state of the cryptographic hash engine so that it         can be forwarded to the storage node holding the next slice of         the object.     -   This continues until the storage node holding the final slice of         the chunk has the cryptographic hash of the entire chunk, which         can be compared to the original cryptographic hash of the entire         chunk. Any change indicates corrupted data.

An alternative technique can provide for more rapid verification of the cryptographic hash of a sliced chunk, but does require more local storage. With this method:

-   -   Each storage node holding a slice of the chunk retains the         cryptographic hash snapshot received from the prior slice and         the resulting cryptographic hash is sent to the following slice.     -   Each storage node can validate on its own that applying the         payload held for its slice of the chunk starting with the prior         cryptographic hash snapshot will result in the same post         cryptographic hash snapshot as recorded. If the result is not         the same, then the stored slice has been damaged.     -   If these snapshots are included in the Roll Call Inventory, or         in a similar transaction, the storage nodes can validate that         their post snapshot matches what the next slice has its         pre-snapshot. If there are mismatches, it indicates that the         chunk has been corrupted. The storage node with inconsistent         data must be identified, and its copy declared to be invalid, so         that regeneration of the slice can proceed.

Summary of Benefits

The presently-disclosed solution has several advantages compared to conventional Object Clusters or conventional Erasure-Encoding Object Clusters. The presently-disclosed solution adds the benefits of erasure encoding for improving utilization of raw storage capacity while preserving the optimizations that the Replicast protocol obtains from the use of multicast messaging.

Specific advantages include:

-   -   The gateway node that ingests the chunk does not have to perform         the erasure encoding algorithm, potentially eliminating a CPU         bottleneck.     -   Network transfers of content are minimized when converting an         object from whole replica protection to erasure encoding         protection.     -   Erasure encoding can be deferred until desirable, radically         reducing the overhead of accepting new content.     -   No metadata modifications are required when changing chunks from         being replica protected to erasure encoded. Metadata references         to the chunk are indifferent to how the chunk is stored.

Conventional erasure encoding with a conventional object cluster places a transactional cost on the use of erasure encoding while reducing the raw amount of storage required to achieve the same protection from lost devices. However, multicast-enabled erase-encoding is better than a conventional object cluster or conventional erasure encoding with a conventional object cluster. Specifically:

-   -   For Put transactions         -   Network bandwidth for put transactions may be optimized. In             contrast, to protect against the loss of two replicas, a             conventional object cluster will fully transmit the object             payload on each of three distinct connections. The latency             of the transaction will be the worst of the three             consistent-hash selected servers.         -   Conventional erasure encoding will transmit slightly more             than 1/Mth of the payload on up to N different connections             to achieve M of N protection. Even with 2 of 4 encoding,             this is still a major reduction in network bandwidth. The             latency of the transaction will be the worst of the M             selected servers, which may be less than a conventional             object cluster for larger chunks, but inferior when the             variance in server latency is high relative to the latency             of putting a chunk.         -   Replicast-enabled object clusters only have to transmit the             chunk payload once to create R replicas. The latency of             completing the write transactions is optimized compared to             consistent hashing solutions because the servers are             typically selected based on their immediate availability.             That is, for example, the 3 most available servers in the             negotiating group will typically be selected to store the             new chunk.         -   The present solution typically defers erasure encoding of             chunks, but even if performed immediately, the chunk payload             is transmitted just as with the above-described “baseline”             replicast-enabled object cluster; effectively transmit once,             receive many, and erasure encode eventually.     -   For Get transactions:         -   A conventional object cluster picks one of the replicas with             which to perform an initial get transaction. When there is             no error, the speed is determined by the average latency of             a storage server within the cluster.         -   A conventional erasure-encoding object cluster must complete             the get of at least M of N slices. Because all slices must             be received at a single chokepoint, and the total amount of             data to be received is increased, this will typically take             longer than with a conventional object cluster.         -   A Replicast object cluster without erasure-encoding must             wait for the best replica's response time.         -   An erasure-encoded object within a Replicast object cluster             will have to wait for the worst time of the N selected             servers, but the M minus N servers with the worst projected             fetch times can be ignored, allowing a slight improvement             over conventional erasure encoding solutions.

CONCLUSION

In the above description, numerous specific details are given to provide a thorough understanding of embodiments of the invention. However, the above description of illustrated embodiments of the invention is not intended to be exhaustive or to limit the invention to the precise forms disclosed. One skilled in the relevant art will recognize that the invention can be practiced without one or more of the specific details, or with other methods, components, etc.

In other instances, well-known structures or operations are not shown or described in detail to avoid obscuring aspects of the invention. While specific embodiments of, and examples for, the invention are described herein for illustrative purposes, various equivalent modifications are possible within the scope of the invention, as those skilled in the relevant art will recognize. These modifications may be made to the invention in light of the above detailed description. 

1-23. (canceled)
 24. A method of distributed parity protection of a chunk stored in an object storage cluster, the method comprising: storing the chunk in a plurality of erasure-encoded slices at different storage servers in the object storage cluster, wherein the plurality of erasure-encoded slices include a plurality of data stripes and at least one parity stripe; determining that a data stripe of the plurality of data stripes is lost; determining surviving erasure-encoded slices of the plurality of erasure-encoded slices; grouping the surviving erasure-encoded slices into a first set of pairs, wherein a first storage server holding a first slice of each pair sends the first slice to a second storage server holding a second slice of the pair; and operating on first and second slices of each pair in the first set of pairs to generate a set of resultant slices, wherein the second storage server applies an operation on the first and second slices to generate a resultant slice.
 25. The method of claim 24, further comprising: further grouping slices in the set of resultant slices into a new set of pairs, wherein one storage server holding a first resultant slice of each pair sends the first resultant slice to a different storage server holding a second resultant slice of the pair; and further operating on the first and second resultant slices of each pair in the new set of pairs to generate a new set of resultant slices, wherein said different storage server applies the operation on the first and second resultant slices to generate a new resultant slice.
 26. The method of claim 25, further comprising: repeating the further grouping and further operating steps a plurality of times until a single slice is generated, wherein the single slice is the data stripe that was lost.
 27. The method of claim 24, wherein the operation is an exclusive-or operation.
 28. A distributed object storage system with distributed parity protection, the system comprising: a network; and a plurality of storage servers communicatively interconnected by the network, wherein the plurality of storage servers include executable code that performs steps including: storing a chunk in a plurality of erasure-encoded slices at different storage servers, wherein the plurality of erasure-encoded slices include a plurality of data stripes and at least one parity stripe; determining that a data stripe of the plurality of data stripes is lost; determining surviving erasure-encoded slices of the plurality of erasure-encoded slices; grouping the surviving erasure-encoded slices into a first set of pairs by sending a first erasure-encoded slice of each pair from a first storage server to a second storage server that holds a second erasure-encoded slice of each pair; and operating on first and second slices of each pair in the first set of pairs to generate a set of resultant slices at the second storage server.
 29. The system of claim 28, wherein the executable code performs further steps including: further grouping slices in the set of resultant slices into a new set of pairs by sending a first erasure-encoded slice of each pair in the new set of pairs from one storage server to a different storage server that holds a second erasure-encoded slice of the pair; and further operating on first and second slices of each pair in the new set of pairs to generate a new set of resultant slices at said different storage server.
 30. The system of claim 29, wherein the executable code performs further steps including: repeating the further grouping and further operating steps a plurality of times until a single slice is generated, wherein the single slice is the data stripe that was lost.
 31. The system of claim 28, wherein the operation is an exclusive-or operation. 